Selasa, Maret 08, 2016

Home Made PLC Trainer

Alat bantu latihan PLC


Homemade PLC and Wiring trainer

Komponen terpasang :
1. Logic schnieder Zelio denga ext. I/O analog 10bit
2. Temperatur display dan thermocouple type k - 600degC
3. Proximity sensor
4. Photoelectric sensor
5. Macam2 relay ac dan dc
6. Alternating relay
7. Contactor
8. Push button, Selector, dan pilot lamp
9. Power supply 24vdc
10. Pressure transducer
11. Masih perlu banyak sensor untuk percobaan - nunggu modal dulu Hehehehe

Rencana pengembangan :
1. Otomatisasi starter motor system
2. Otomatisasi booster pump system
3. Otomatisasi proses produksi
4. Masih banyak lainya.... Tergantung kebutuhan anda

Programming dengan menggunakan Zelio soft dari Schneider yang dapat menggunakan ladder diagram dan FBD (function block diagram)

Semoga berguna bagi yang membutuhkan...

Rabu, Maret 24, 2010

WORKSHOP ELECTRO MECHANICAL

Pada Agustus, 2006 di kawasan Kelapa gading telah terbentuk sebuah perusahaan untuk menangani pebaikan peralatan listrik dan mekanik, ialah PT. BINTANG LESTARI PERSADA familier disebut dengan “BLP” saya telah bekerja di workshop ini dari awal berdiri.

Workshop ini memiliki memiliki kapabilitas dalam memperbaiki :

  • Motor AC Low – HighVoltage.
  • Motor DC dan Generator.
  • Transformer, Reactor.
  • Turbine Uap, Gas, Angin, Air.
  • Pompa Centrifugal, diapram, Multistage, Vaccum.
  • Plate Heat Exchanger, Separator, Screw Decanter.
  • Air Conditioning System, Boiler System.
  • Turbocharger.
  • Dynamic Balancing, and Motor Test Bench.
  • Engineering consultant untuk minning dan oil & gas.
  • Marine Power service.

Untuk informasi lebih lanjut bisa datang ke workshop kami di alamat sebagai berikut : clik disini 

Pada saat ini saya telah mendapatkan pelajaran yang sangat banyak di tempat ini, dari sistem kerja pompa hingga jaringan yang terhubung ke sistem tersebut.

Selasa, Januari 12, 2010

near the future

Managing the Complete Motor System

Modern management practices often do not take into account the importance of motor systems maintenance and management requirements. Through efforts in cost control, many industrial and commercial firms reduce maintenance staffs, take least cost approaches to corrective actions and sacrifice preventive maintenance programs. The result has been increased energy costs and downtime resulting from equipment not operating to full potential and failing unexpectedly. The problem results in $100’s of billions of dollars in additional energy consumption and lost revenue. Unfortunately, in many cases, the connection between the cause and effect is not made.

There are specific issues with defining the philosophy of motor management. The most important is that many view motor management as energy management; others view it as motor testing, storage, greasing or some other function. These limited definitions are wrong and will destroy a program before it is started.

Why? Because they are merely functions and don’t include a long-term philosophy. A true motor management program and philosophy will have both immediate impact and long term results.

Therefore, a more accurate definition of motor management is required:

Motor system maintenance and management is the philosophy of continuous improvement of all aspects of the motor system from incoming power to the driven load. It involves all components of energy, maintenance and reliability from system cradle to grave.

This provides the outline for any true motor management program which is intended to extend the useful life of the motor system, combined with continuous improvement and availability of the system. In addition, the focus is back on a systems approach, so that the system includes: Incoming power and distribution; Controls; Motor; Coupling; Load; and, Process. A full view of the system is sorely lacking in most programs.

In this article, we will discuss the motor system components and how issues within each component can affect the system, as well as some of the key issues and a few of the technologies used to evaluate those conditions.

While the past articles in this series have focused on testing as it relates to the electric motor (also called the electric machine) the purpose of this article is to expand the series to include testing and managing the complete system.

Incoming Power

Starting from the incoming power to the load, the first area that would Distributionhave to be addressed is the incoming power and distribution system.

The first area of issue is power quality and then transformers. Power quality issues associated with electric motor systems include, but are not limited to (there are many issues, so we are just covering the common ones here):

Voltage and current harmonics: With voltage limited to 5% THD (Total Harmonic Distortion) and current limited to 3% THD, current harmonics carry the greatest potential for harm to the electric motor system;

Over and under voltage conditions: AC induction motors and most modern drives are designed to operate at no more than +/- 10% of the nameplate voltage.

Voltage unbalance: Is the difference between phases with a maximum of 5% voltage unbalance and recommended less than 2%. The relationship between voltage and current unbalance varies from a few times to many times current unbalance as related to voltage unbalance, motor design and other power quality issues in the system. The relation can be anywhere from 3x to over 20x voltage to current with the higher multiplier being related to such things as power factor differences between phases, impedance, motor load, etc. In a ‘perfect’ system, the current unbalance is limited to 7x, under full load, per the NEMA MG-1 standard.

Power factor: The lower the power factor from unity, the more current the system must use to perform work. Signs of poor power factor also include dimming of lights when heavy equipment starts.

Overloaded system: Based upon the capabilities of the transformer, cabling and motor. Detected with current measurements, normally, as well as heating and over-heating issues. The primary tools used to detect problems with incoming power include power quality meters, electrical signature analysis and voltage and current meters. Knowing the condition of the motor system power quality can identify a great many phantom problems.

Transformers are one of the first critical components of the motor system. In general, transformers have fewer issues than other components in the system. However, each transformer usually takes care of multiple systems in electric motor and other electrical systems.

Common transformer problems include (oil filled or dry-type transformers):

• Insulation to ground faults;

• Shorted windings;

• Loose connections;

• Electrical vibration/mechanical looseness; and,

• Overheating, arcing or partial discharge in oil filled transformers.

Test equipment used for monitoring the health of transformers include but are not limited to:

• Motor Circuit Analysis (MCA) for grounds, loose/broken connections and developing shorts;

• ESA for power quality and late-stage faults;

• Infrared analysis for loose connections;

• Ultrasonics for loose connections, severe faults and bushing problems;

• Insulation testers for insulation to ground faults;

• Turn-to-Turn Ratio meters for winding shorts; and,

• Oil analysis for most conditions in an oil-filled transformer.

MCC’s, Controls and Disconnects

ControlsThe motor control or disconnect provides some of the primary issues with electric motor systems. The most common for both low and medium voltage systems include:

 

 

• Loose connections

• Bad contacts including pitted, damaged, burned or worn

• Bad starter coils on the contactor

• Bad power factor correction capacitors which normally results in a significant current unbalance.

Additional systems include AC and DC drives, soft starts, amplifiers which we will address in future articles.

The most common test methods used for evaluating controls include infrared, ultrasonics, volt/amp meters, ohm meters and visual inspections. MCA, ESA, ultrasonics and infrared normally provide the most accurate systems for fault detection and trending.

Cables - Before and After Controls

Cabling problems are rarely considered and, as a result, can provide some of the biggest headaches when troubleshooting. Common cable problems include:

• Thermal breakdown due to overloads or age

• Contamination which can be even more serious in cables that pass underground and through conduit

• Phase shorts can occur as well as grounds. These can be caused by treeing or physical damage

• Opens due to physical damage or other conditions

• Physical damage is often a problem in combination with other cable problems.

Testing ad trending can be performed with MCA, infrared, insulation testing, ESA and partial discharge.

Electric Motors

Electric MotorElectric motors include both electrical and mechanical subsystems. In fact, an electric motor is a converter of electrical energy to mechanical torque. The primary mechanical problems include:

 

• Bearings - General wear, misapplication, loading or contamination

• Bad or worn shaft, mechanical fits or bearing housings

• General mechanical unbalance and resonance.

Vibration analysis is the primary method for detection of mechanical problems in electric motors. ESA will detect late stage mechanical problems as will infrared and ultrasonics.

Primary electrical problems include:

• Winding shorts between conductors or coils

• Winding contamination

• Insulation to ground faults

• Air gap faults, including eccentric rotors;

• Rotor faults including casting voids and broken rotor bars.

MCA will detect all of the faults early in development. ESA will detect late stage stator faults and early rotor faults. Vibration will detect late stage faults, insulation to ground will only detect ground faults which make up less than 1% of motor system faults while surge testing will normally only detect shallow winding shorts and all other testing will only detect later stage faults.

Coupling (Direct and Belted)

Load and ProcessThe coupling between the motor and load provides opportunities for problems due to wear and the application. Some of the more common issues include:

 

 

• Belt or direct drive misalignment

• Belt, sheave or insert wear;

• Belt tension issues are more common than most think and usually result in bearing failure

• Overhung load issues.

The most accurate system for coupling fault detection is vibration analysis. ESA and infrared analysis will normally detect severe or late stage faults.

Load and Process

CouplingThe load and process can have numerous types of faults, depending on the type of load. The most common are worn parts, broken components and bearings. Test instruments capable of detecting common load and process equipment problems include ESA, vibration, infrared and ultrasonics.

 

Conclusion

While we have focused on the primary elements making up a single electric motor system, it is not suspended in space. A full systems approach includes taking into account the overall operating environment, from surrounding equipment to altitude.

However, as we continue to expand our knowledge of addressing the motor system, it is important to isolate the components, then the system, then the environment in order to gain the understanding necessary to truly evaluate the conditions of systems from a standpoint of reliability.

The optimal method for evaluating a complete motor system is to step back, view the complete system and environment, don’t sweat the details, then focus on the areas that make the most sense. This also includes the development of an overall Reliability-Centered Motor Management (RCMM) strategy, which must encompass all of the aspects of the motor system life-cycle from initial purchase to final retirement.

As we continue this series, we will now step back and tackle each of the specific components outlined within this article and how each impacts the overall system

Sabtu, September 19, 2009

DASAR – DASAR STEAM TURBINE

PRINSIP KERJA TURBIN UAP
Turbin adalah pengganti sistem penggerak dasar dalam industri dan transportasi laut, di gunakan di daerah operasi yang tidak boleh terkena kontaminasi dari api atau percikkan lonjakan listrik. saat ini penggerak sistem uap sudah banyak tergantikan oleh motor listrik dengan kelas IP anti ledak tetapi di sebagian area tetap di gunakan dengan pertimbangan biaya operasional.
Dasar yang di gunakan untuk memutar ROTOR turbin adalah Uap bertekanan tinggi di semprotkan melewati nozzle untuk akurasi semburan, pada ROTOR TURBIN terdapat banyak sudu atau blade untuk menahan dorongan dari uap sehingga menimbulkan gaya gerak.
Skema Perjalanan Uap :
 
Gambar di atas adalah sistem turbin chiller
Sistem efisiensi turbin terbagi menjadi dua kelompok, yaitu :
  1. Turbin Impulse
  2. Turbin Reaksi
Skema Perbedaan Tipe Turbin
Skema diatas menjelaskan perbedaan prinsip penggerak dari turbin yang berbeda tetapi sebagian besar produsen telah menggabungkan sistem tersebut, di bagian tekanan tinggi digunakan sistem Impulse dan di bagian tekanan rendah di gunakan Reaksi agar sistem kerja menjadi berimbang.
besok kita tambah lagi………

Jumat, September 11, 2009

Dual Roll Crusher System for Mining application

Roll Crushers are compression type crushers, and were once widely used in mining. They have, within the last 10 or so years, fallen into dis-favor among mining and processing companies. The probable reason is because the large mines require very large crushed product output with minimal cost, makes the roll crusher uncompetitive. The roll crushers are not nearly as productive as cone crushers, with respect to volume, and they do have a little higher maintenance associated with them. Roll crushers do, however, give a very close product size distribution, and if the ore is not too abrasive, they do not have high maintenance costs.

Roll crushers have a theoretical MAXIMUM reduction ratio of 4:1. If a 2 inch particle is fed to the roll crusher the absolute smallest size one could expect from the crusher is 1/2 inch. Roll crushers will only crush material down to a minimum particle size of about 10 Mesh (2 mm). A roll crusher crushes using compression, with two rolls rotating about a shaft, towards the gap between the rolls. The gap between the rolls is set to the size of product desired, with the realization that the largest feed particle can only be 4 times the gap dimension.

The particles are drawn into the gap between the rolls by their rotating motion and a friction angle formed between the rolls and the particle, called the nip angle. The two rolls force the particle between their rotating surface into the ever smaller gap area, and it fractures from the compressive forces presented by the rotating rolls. Some major advantages of roll crushers are they give a very fine product size distribution and they produce very little dust or fines. Rolls crushers are effectively used in minerals crushing where the ores are not too abrasive and they are also used in smaller scale production mining of more abrasive metal ores, such as gold. Coal is probably the largest user of roll crushers, currently, though. Coal plants will use roll crushers, either single roll or double roll, as primary crushers, reducing the ROM coal. Usually, these crushers will have teeth or raised forms on the face of the roll. (Roll crushers used for minerals and metal ores have smooth faced rolls.)

MODERN PUMP

ADVANCE PUMP FOR TODAY ENERGY SAVER…….

Do you need more energy or do you need to lower your cost of electricity payment. Here is solution for you :

Small pump for generate high efficiency water supply to meet your need but no need to pays more electricity cost, compact design and very reliable.

Hydra-Cell Design Advantages

· Positive displacement with smooth low pulse output.

· Heavy-duty industrial construction for long service life in harsh conditions.

· Hydraulically-balanced, unstressed diaphragms.

· Wide range of flow rates from 0.4 to 128 l/min and pressures up to 170 bar.

· Repeatable, accurate output – ideal for metering and dosing.

· Seal-less design – can pump particles in suspension.

· Flexible installation with a variety of mounting configurations.

· Minimal maintenance.  No cups, packings or seals – can even run dry!

· Wide choice of materials of construction for pump heads, diaphragms and valve assemblies..

· High efficiency – low power consumption.

· Compact construction – physically small in relation to performance.

clip_image001

1. Drive shaft - via electric motor, hydraulic motor, belt and pulley etc.

2. Roller bearings - rigid support, immersed in lubricating oil bath.

3. Fixed-angle cam - translates rotary motion into linear to the hydraulic cells.

4. Hydraulic cells - displace diaphragms via pressurised oil.

5. Diaphragms - hydraulically balanced, no stress during flexing.

6. Inlet valve assemblies - simple design, allow liquid into pump chamber.

7. Outlet valve assemblies - allow liquid to flow into pressure discharge line.

8. Pressure regulating valve - controls outlet pressure and prevents pump overload.

Ref : http://www.wannerint.com/Pump+Design

Selasa, September 08, 2009

Jogjakarta Earthquake – 07 Sep 2009

 

Gempa telah terjadi lagi di jogjakarta, tetapi tidak seperti tahun 2006, skalanya sekarang ringan dan tidak berpotensi sunami…………….

kenapa akhir akhir ini sering terjadi gempa ?

Kutipan kata KEPSEK BMKG Yogya , Tony A Wijaya :

Gempa tektonik berkekuatan 6,8 Skala Richter (SR) mengguncang sebagian wilayah Daerah Istimewa Yogyakarta (DIY), Senin malam pukul 23:12:24 WIB, dan menyebabkan sebagian warga berlari ke luar rumah untuk menghindari hal-hal yang tidak diinginkan.

Menurut Kepala Seksi Data dan Informasi Stasiun Geofisika Badan Meteorologi, Klimatologi dan Geofisika (BMKG) Yogyakarta Toni A Wijaya di Yogyakarta, Selasa dini hari, gempa tersebut berpusat di laut dengan jarak 253 kilometer tenggara Wonosari, ibukota Kabupaten Gunungkidul, DIY.

Pusat gempa berada pada 10,33 Lintang Selatan - 110,62 Bujur pada kedalaman 35 kilometer.

Menurut dia, gempa tersebut tidak berpotensi tsunami karena berpusat di tengah laut, yang jauh dari pantai.

Ia menjelaskan gempa disebabkan oleh penunjaman lempeng Indoaustralia terhadap lempeng Eurasia.

Guncangan gempa dirasakan oleh sebagian warga di wilayah Kabupaten Bantul, dan Kota Yogyakarta. Sebagian dari mereka berlari ke luar rumah, dan menunggu beberapa saat sebelum kembali masuk ke dalam rumah.

"Di Wonosari sendiri, guncangan gempa tidak begitu terasa karena batuan di wilayah itu lebih padat," katanya.

Oleh karena itu marilah kita merenung sejenak tentang segala sesuatu yang akan kita lakukan di masa mendatang……

pelajaran berharga yang diberikanoleh alam.

My Life, My Passion, My Desire