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This is your very first post. Click the Edit link to modify or delete it, or start a new post. If you like, use this post to tell readers why you started this blog and what you plan to do with it.
There are some situations that require an approach that is unlike anything that you can find elsewhere. This is true in nearly everything at some point. It is true in the application of power supplies. In fact a custom power supply is far more common than a number of other custom things. The reality that exists around power supplies calls for a certain amount of customization. Even in the standard models there are features that have options. For those applications that demand far more than the typical job though there are custom power supply options.
Among the many variations that exist in both standard and custom units are the methods of power input. Note that very few power supplies generate power. That task is reserved for a device called a generator. Instead a power supply accepts power, but then outputs it in a form that is required for particular equipment. Among the most common changes are regulations of voltage. For instance a low volt energy supply may be put into the device and then high voltage energy is output. That is the basic concept of a power supply. The method of input is something that varies.
The most common form is electrical. Both AC and DC may be accommodated though. This is also true in a custom power supply unit. In a custom unit you might present a need such as ‘constant power’. Toward that end a custom unit might be designed to accept multiple power inputs. For instance it might be hardwired to the electricity at a location. In addition it may have a source in from a battery. This would provide energy when the electricity was out. An array of renewable sources could also be connected as well.
The next common variation is the regulation that the unit can provide. Within the unit is any number of additional mechanisms. In some cases these may provide the capabilities of remote switching or other options. Remote monitoring is also possible with some units. Each of these specialized internal functions may be specific to the unit.
Lastly the output is a feature that has a number of options. For instance it is possible to find a standard unit that supplies only one energy rating. Others may allow for switching between ratings. This is also true with a custom power supply. These shape function and create convenience in many cases. The options that you choose will likely be based on the specifics of the application you are selecting a unit for.
When you are creating a custom unit there is the possibility that you may need to combine one or more of these options. The result can be an effective device that supplies all that you need. When the creation is not handled well the result can be inconsistent performance and other problems. Each aspect of the environment that the unit will be performing in should be considered. Similarly the intended function of the unit and the preferences of the users should be considered.
Power Supply Cords is a physical medium of Supplying electricity which can be detached from the main power source to any electrical appliances. Power Supply Cords are flexible cords with electrical plugs at both the ends, one male and one female. The wire cable connecting both ends are termed as cable assembly which consists of a conducting medium, basically copper strands that covers the cords fully and acts as an insulating material and cover the outer area with either polymer or rubber jacket which protects the wire.
Power Supply Cords is the one end that is permanently fixed to that electrical equipment or appliance, and the power cord sets is that cord set that can be utilized anywhere that electrical appliance or equipment is used. It can be used in office, industries, commercial and domestic area. Extension Power Cords are the long wire cable or the cord set that helps the equipment to be connected to any electrical supplies or the source which is far away from the place of that equipment where it is being used. These extension power cords are used in various applications like lighting, sound equipment, shop equipment and in many other domestic settings. NEMA power cords are the standard for North America Electrical plugs, cord Voltage capacities and electrical receptacles configuration. These are according to the North America Standards rest is different standards that are set for International market also termed as ‘International Power cords’. There are also plug adapters to reconcile NEMA Plugs with International Sockets.
Male plug is One End of the power supply cord that connects the electrical receptacle, electrical outlet or power supply and the female plug that connects to the electrical equipment or the appliance. Power Supply cord manufacturers manufacture power cords according to different regions and countries as they have some different voltage standards and electrical receptable configurations which may or May not interchangeable with cords from other locations. The North American standards are termed as National Electrical Manufacturer’s Association (NEMA) standards for power supply cords and they are different from the International Standards. NEMA standards have come out with 15 different types of power supply cords which cannot be used or interchanged outside North America.
Consider many factors While Selecting the power cord type for different applications. Power cord manufacturers follow various specifications that include voltage rating, current rating, jacket material, safety, length, wire shape and size and maximum cable temperature. The application determines the type of jacket material is best suited for that cord. Jackets also range from thermoformed from PVC, rubber, polychloroprene and textile construction. The size of power supply cord or the electrical wire is determined by the amount of voltage that will be passed through the cord. The NEMA sets company standards for both male electric plugs and female electric plugs. An Electric plug is polarized when the physical characteristics of the blades allow the plug to be connected to the electrical outlet in only one way. Polarization and grounding is necessary for increasing higher voltage appliances and electrical equipment that could be higher risk of electric shock when they become live.
There are a variety of power supply cords in the market depending upon its gauge sizes, application for which it will be used (heavy, mid, low), awg sizes, insulation’s and various jackets. It includes International Power Cords, Cord Sets, AC Power Cords, Electric Cords, Electrical Receptacles, Electrical Plugs, NEMA Power Cords, Cord covers, Power Supply Cords, Extension Cords, Cable Assembly and Plug Adapters & Plug Covers. All the above Electrical plugs and wire cables are used in different applications with high, mid and low density.
The aspect of having something like nothing else on earth is rather appealing to many. That appeal does not always have much weight in the world of power supply units though. Instead in the world of power supply units there is sometimes a necessity involved in having something like nothing else on earth. When you combine all the aspects of the environment and the function of any particular power supply the reality is that it is quite different than any other power supply. Despite that reality standard power supplies are able to fill the needs in most cases. This is a result of the versatile designs and the functional ranges that those versatile designs allow for. In some cases you may find though that the standard options simply will not do despite their versatile ranges.
For those instances the world of power supplies has another option. You can name your specifications. As simple as that, you can list your demands and custom power supplies can be fabricated to meet those requirements. The positive potential is nearly unquantifiable. What this allows is that you specify the input capabilities of the unit. You can specify the internal functions of the unit. You can specify the output of the device. You can specify the conditions that the housing must be suitable for. These are the realities of custom power supplies. In some cases you may find that the potential is a bit overwhelming.
There are models of course. You can begin with the basic design of a standard power supply. Now list everything that you need to change about that design. Using this step-by-step approach you can begin to shape the custom power supplies that will truly provide a unit that can benefit your operation. It is important that you not become too single-minded though. You see there are follow-up steps that will benefit you even more. For those steps you need to describe what you want it to do in your own words. Describe the unit of your dreams.
Now take both your description and the unit that you have adapted and talk to a professional. You can usually find custom fabrication solutions at many of the larger manufacturers of standard power supplies. These individuals are the professionals that will help you to refine your custom power supplies. You can show them both your description and your adaptation, then listen. Even if you ultimately decide that they are not the best choice to fabricate your unit you can learn a lot during the talk. Take the information that they provide about options and limitations. It can serve as a basis to compare fabricators and dream bigger.
When having a custom unit created there is little reason to leave the individuals that work with the unit and service it inconvenienced. They and your operation are in a position to benefit from the custom unit. Overcoming obstacles that could not be addressed by standard options is only the first level of customization. When you begin to make things better than imagined then you are beginning to take advantage of a whole new level of customization. Productivity can increase along with the ease that you create.
In our world today, the quality of a personal computer is often measured only by its processor speed, memory capacity, and hard drive space and for gamers, the quality of the video card. Sometimes, the computer monitor will grab some attention, especially if it has an LCD screen. Seldom, however, do we think of a computer by its power supply. And seldom do we give them an upgrade, even if we have upgraded each and every other computer component.
But when the power supply is damaged or stops working, we have to think about it, or we have no computer period. The only solution is a power supply replacement.
There are a lot of computer power supplies available in computer shops, so finding one should not be difficult. Replacing your power supply with a new unit should also be easy. The hard part is selecting the power supply that your computer needs. There are different kinds of power supplies and each has different specs. For your computer to work properly, it must be equipped with the right one.
There are two basic things to consider whenever you are buying a new power supply for your computer — power requirements and the power supply’s form factor.
Modern power supplies have power outputs that range from 200 watts to 500 watts. Before purchasing a new power supply, you must first know the amount of power that each of your computer’s components need. These power requirements can usually be found on the labels of the components themselves. By adding up these figures, you’ll have a good estimate of the power output your new power supply should have.
As a general rule, never buy a power supply with output ratings that are lower than your estimates. Neither should you buy those that have too high a power rating, as most of this power would simply be wasted.
The standard form factor used on most PC power supplies today is the ATX-form factor. Not all power supplies, however, use this standard. If you have an older PC, it must be using a power supply in the AT-form factor. There are also less common form factors today like the TFX and BTX form factors. Before purchasing a new power supply, identify first what form factor would fit on your PC or else there’ll be no way for you to use it.
The DC Power Supply is a rather fundamental electronic device, however there are hundreds of DC Power Supply products on the market from dozen of manufacturers. Narrowing down the best product for your application and budget can be a daunting task. This article addresses DC Power Supply differentiators, functions and the applications they are best suited for. The article’s focus is DC Power Supplies used by engineers, manufacturers, quality professionals and electronic hobbyists for the purposes of R&D, manufacturing and testing.
Power Supplies can range in price from $50 to $20,000 and the cost is often directly proportional to the amount of power the device outputs. The primary function of a power supply is to regulate output voltage and current. It takes an input power and regulates the output power as to enforce a constant voltage and current. In the case of DC Power Supplies, the input power is converted from alternating current (AC) to direct current (DC). There are two basic types of regulated DC Power Supplies: Linear and Switching.
Linear power supplies can never output a higher voltage than the input source. In theory, a linear power supply that is driven by typical 110V wall outlet could only output 110V, assuming the device were 100% efficient. Realistically, no power supply is 100% efficient because power conversion always results in energy loss, usually in the form of heat dissipation. Therefore, linear power supplies usually output voltage that is significantly less than the input.
Switching power supplies can step-up, step-down or invert the input voltage. Switching power supplies are usually larger, noisier and more expensive than their linear counterparts, however, switching power supplies are typically more efficient.
Choosing the right DC power supply for your application requires definition of some basic design specifications: voltage range, current range, number of outputs, power cleanliness (known as “ripple”) and programmability. In general, the higher the output voltage and the lower the ripple, the more expensive the DC Power Supply. Multiple outputs and programmability features will also add to the cost.
The least expensive DC Power Supplies are ideal for electronics hobbyists and basic electro-mechanical applications where only raw power is required. It is likely that the devices being powered in these applications already have power-conditioning features that eliminate the need for precision input power. Low power, single output, DC power supplies range in price from $50 to $200.
Mid-range power supplies are best suited for non-critical, laboratory projects involving more advanced electro-mechanical applications or basic board-level testing. Mid-range power supplies might have multiple outputs, higher power ratings, lower ripple and precision, digital metering (+/- .001V, +/- .01A). Mid-range DC power supplies can be linear or switching and could range in price from $200 to $1,000.
High-end applications requiring high output voltage, advanced programmability (GPIB PC Interfaces), numerous outputs and very low ripple should budget in excess of $1,000 for their DC power supply. Many laboratory, R&D and testing applications could easily spend $5,000 to $10,000 per power supply.
This article has introduced some basic features and applications of DC Power Supplies. Before making your final purchase, be sure to consult the manufacturer and thoroughly understand all the specifications of a particular product. Choosing the best and most economical DC Power Supply for your application does not have to be a complex and time-consuming task. By identifying your design parameters, you will quickly narrow down product selection to a niche class of products from only a few manufacturers.
Quite often whenever electronic equipment don’t function or work, we would immediately suspect a faulty switch mode power supply. But do you know that defective or shorted components in the motherboard or main board could cause the power supply to stop working too?
Switch mode power supply (SMPS) are designed so efficiently that whenever there is any short circuit occur in the main board the power supply would shut itself off and totally stop working. If you have no experience about troubleshooting switch mode power supply, you may think that the power supply have problem where in fact the main board is the real cause of no power problem.
Switch mode power supply have a current sense circuit (if you look at UC3842 PWM IC pin 3, it stated I-sense which mean current sense) and if there is short circuit in the secondary side (either in secondary diodes or main board), the current drawn would be increase and this will lead the PWM IC to stop generating output to the power fet and thus the power supply would shut down. All this happen in a split of seconds and you do not have the chance to know if there are output voltages at the secondary side.
Some older design of SMPS power supply do not use the PWM IC, but it do have the circuit to detect over current drawn and shut itself down whenever it detects a shorted component in the secondary side. One good example was the power supply used in printer. Printers usually have two boards; one was the power supply while the other was main board. If there is any short circuit in the main board, the power supply would not work. In order to isolate at where the problem is, one must remove the connector from the power supply board. Once the supply connector to the main board was removed, you can now switch on the printer and check if there is any voltages present at the power supply connector.
If there are zero voltages measured across all the supply (VCC) pins then we can conclude that the power supply have problem and you can put your whole concentration in this power supply board. What if there are voltages measured across the connector? This means that the main board is causing the no power problem most probably due to some shorted components in the main board.
For your information, dot-matrix printers usually required two voltages to function. One is the 5 Volts (for logic IC, eeprom and CPU) and the other is 30+ volts for the motors. The question now is how do we know if the main board is the main cause that shutting down the power supply? Very simple, just use your analog multimeter set to X 1 Ohm and measure between the supply pin (say 5 volts pin) and the main board ground and then reverse the probes. A good board should not show two similar reading and if you get two similar ohms reading then this means that the 5 volts line had shorted to ground through some faulty components.
If you have confirmed that the 5 volts line have problem then how do we find out the culprit since there are so many components connected to this line? TTL IC’s, CPU, EEPROM, transistors, diodes and even small filter capacitors are all connected to the 5 volts line. Either one of these components shorted could cause no power to the printer. You may remove each components lead (5 volt supply) in the main board and hope that the short circuit will be gone. Assuming if you happen to remove one of the filter capacitor pin and the short circuit is gone then we can say that the real culprit is the filter capacitor.
The real problem is what if the board has many components on it and this will consume lots of your time to isolate the problem by removing one pin at a time. It is not easy to identify the supply 5 volts pin to a spider IC that has 100 pins or more. Many spider IC’s have more than one 5 volts supply pin. Some even have 4 and some have 6 to 8 supply pins. Does this mean you have to check one pin at a time until you finally locate the fault? Not only that, to remove the supply pin from the spider IC’s and check for any short circuit between the grounds required a very good skill too. If you messed out the circuit board track, the main board can then be considered beyond repair. Even though you can repair the broken circuit track, this does not mean you have solved the actual fault!
Do you see the extra problem arise when you try to find out the fault? There must be some better way to tackle this kind of problem. Yes it is true that one can use ESR meter to slowly track to the source of the short circuit You can utilize the ESR meter to locate short-circuits on electronic boards by checking the actual track resistance. One probe connects to the ground and the other to the circuit line and if the measurement rises as you probe further along the track, you know that you are heading to the wrong direction! If the ESR value decreases as you move along the track then you are in the right direction. The problem is what if the main board has double layers, 4 or even 8 layers? You may be wasting lots of your precious time trying to track to the actual fault using the ESR meter method! After explaining so much about the problems, now is the time that you are waiting for to get the answer on how to solve this kind of fault fast.
Do you know that the DC regulated power supply besides using it to power up electronic circuit it can also be use to troubleshoot and find out a shorted component in a motherboard? Assuming you have confirmed that the VCC supply lines shorted to ground through some faulty components, you can easily detect it with the use of a variable digital DC regulated power supply. If you don’t have the digital one you can always use one with the analog panel meter which is cheaper.
Now connect the alligator clip from the positive output supply to the 5 volts VCC pin in the main board and the negative output to the main board ground as shown from the picture. Once everything was done, it’s time to switch on the dc regulated power supply. Slowly vary the knob clockwise and see the voltage increase. At the same time the current draw can be seen from the current digital meter readout. From experienced, if there is a short circuit in the main board, whenever the voltage is increase, the current will rise dramatically and if no short circuit there would be less current draw.
Okay back to this problem, if you observe that the current drawn also increase (rapidly) as proportion to the rise in voltage setting, you are now for sure that there is component shorted in the main board. What does this mean? It is a good news to us, because if the current drawn too much we can know the culprit by touching on the hottest components in the main board. Using your finger you can touch on any components that are very hot. Touch on the IC’s, diodes, transistors, capacitors and etc. Once you located that only one component that is extremely hot to touch then that was the culprit! That’s the real cause that you are trying to find! I’ve used this method to solved lots of main board problem and usually the culprit turned out to be a defective gate array and ram IC.
Why don’t I immediately turn the output voltage from the dc regulated power supply to 5 volts since the defective main board is also using 5 volts to run? If I do this and if the faulty components turned hot too fast, I’m afraid this will lead the faulty component to open circuit. If the faulty component open circuit, the current draw will drop and the only clue that you have to identify the culprit has been destroyed! If this thing happens then you may not have a higher rate to repair the board. Of course you still can by replacing one by one the SMD spider IC’s but this will surely eat up lots of your repair time.
The above method I’ve just mentioned is not limited only to printer main board; it can apply to other type of board as well like the computer motherboard, hard disk, dvd, vcd, industrial board and etc. Get a DC regulated power supply and I’m sure you can detect shorted component in the main board in the shortest time possible! By the way the specification of the DC regulated power supply that I’m using was 5A 30 volts (variable type). Have a good day my friend!
People are trying a lot of things to relieve their wrist pain due to computer mousing the whole day. Some may have even used some floating supports that can move along with the mouse, while others end up bandaging their hands and wrists in order for the two to move along with each other. Surprisingly, a lot of these tricks do not help at all.
As far as we all know, it’s hard to know whether you are already afflicted with carpal tunnel syndrome or not. Said syndrome is characterized mainly by tingling, weakness in the hand area, numbness, pain in the hands and wrists area. The same syndrome can also be caused by Ganglia. This is another hand ailment different from the carpal tunnel syndrome. Your physician may or may not require you to wear a wrist support.
One of Ganglia’s physical evidence is a small bump on the base of the thumb. Some may have a ganglion cyst, which can be drained through aspiration or will likely return on its own.
A lot of people would easily suggest that you change your job. But it is easier said than done. There are just some people who cannot leave their current job just for them to get cured from whatever type of illness they are having, let’s say carpal tunnel syndrome or a ganglion. The pain that the sufferer can get from ganglion is a bit distracting. There is also a chance that one can easily lose the strength in their affected hand.
With a bit of researching, you can still work with a small tablet, this is if you’re used to using a bigger tablet. This is also cheaper than the big ones. While most new devices needs some adaptation time, you will be surprised about the said concept. You can replace your mousing days with a pen or stylus. You can easily navigate anything just like you are used to doing with a mouse.
Whether or not your bump will get cured, there are other alternatives to using a mouse. The tablet is one. What’s important is that you let your hand and wrists heal from its ailment. And be pain free again.