Hazard From Stung Electricity Result

Once we know the simple way how to test electrical wiringwithout tools in advance. It is not wrong if we also studied the impact or effect of the electric shock. The human body actually has custody, when electrified. Resistivity or resistance on the human body is different, whether it is fat or skinny body affects the body's resistance.

From the results of a study obtained data is that the human body is so varied prisoners. However, the data obtained from these results that the average person who has custody of the body thin between 100 000 ohm (100 Mega Ohm) up to 500 000 Ohm (500 Mega Ohm). In contrast to fat people, fat people have barriers around 5000 Ohm (5 Mega Ohm) even less. If we look at the data of the human body barriers, which one would be more severe when an electric shock?

We know that the electric current moves from high potential to low potential. So the electric current moves from the source toward ground. We will feel the electricity when holding the rate of electrical current that travels through the body we headed to ground. So what if the electric current is confronted with obstacles? Sure he will add the amount to be through these obstacles. From here we can see that the greater the obstacles the greater the electricity needed to go to ground.

So do not blame if we were having a thin body is more pronounced when the electric shock rather than fat. We also have seen the video of events people were electrocuted to burn his body, when the voltage available at the wires only about 220 volts, and the time is also only briefly. The question is, why the person may get burned? If we look at the condition of the person, the chance that they are not fat to be more severe when an electric shock.

Here is the data condition of our body when exposed to electric current in general:

Due to the large electric current

0.1 Amperes to 0.8 Amperes Feels tingling, even to pain

0.9 Amperes to 1.5 Amperes Feels sting, and still conscious

1.6 Ampere to 2 Ampere Feels shocked, until he was unconscious

2.1 Ampere to 5 Ampere Fainting, can be difficult to breathe

5.1 Amperes to 10 Amperes Fainting, probably died

More than 10 Ampere Burned

From the table, we can find out how much electrical current is flowing and how dangerous when we are exposed to the electric current. Electric shock here in question is more than 5 seconds. That's it, may add to our knowledge about the world of electricity. Hopefully useful, and do not forget to give constructive criticism and suggestions. In order to be better in the next article creation for writers. Thank you for visiting, and thanks for giving judgment on this web.

Knowing Easy Ways Without Power In Cable Tools

Electricity is the main source in the operation of electronic devices that we have. Electricity can flow when there is conduction and also their potential difference. No electrical conductivity of various kinds, ranging from air, water, salt, copper, iron, and so forth. Electricity can not flow on an object that is isolation. Objects that have insulating properties in general is the main ingredient objects made of rubber ores, such as plastic, and rubber. Thus, in the manufacture of safety conductor materials (materials that can conduct electricity), we often encounter such material is covered by an insulating material. Examples of frequently encountered is wired in series installation of our household, and also wiring of our electronic tools.

From household wiring and electronic cables we had, we could have electricity in our daily lives. We need to know, in fact electricity is something that is not visible but we can feel its presence. Here means the electricity has the same properties with ghosts, ie not visible and we can feel its presence. Electricity actually has two sides, the good side and a bad side. I think this is reasonable, because all the things that exist in this earth definitely has two sides, both the good side or the bad side. A simple example, we know that water is the source of life for all living things (which has a soul). Here means that we know better than the side of the water. However, the excessive amount of water that can kill a living creature. A simple example is if we drink too much water when we swam middle of the lake or the middle of the ocean, we will experience a loss of consciousness (fainting) until death.

From these two we know exactly what risks we face if we are dealing with electricity. Both high voltage and small voltage electricity all at risk, just how do we minimize the risk. Gains or both sides of electricity is that we can operate a matter that requires a power source. While the loss or the bad side, we can not operate a matter that requires a power source. If we are adjacent to or in contact with a conductive electrified then we'd been stung by it. Possibly the worst of the shock it is death for us.

So how to keep us safe in the face of such a situation, a situation where we are adjacent to or in contact with live electrical conductors. In frequent cases, our electric shock on the conductor (cable) because of ignorance we will their electricity on the cable. We can test or check the cable with tools like AVOmeter. What if, in these conditions we do not have the tools? Definitely we will be looking for help or seek a loan instrument to a neighbor or friend nearby in our Area. So what if at that moment we are faced with a situation where we do not have the tools, and we are also in a state of their own. Are we going to let go, and wait for destiny without having to try trying out how we know the condition of the cable.

If we say no, and we are trying to try to determine the condition of the cable, apaka no electricity or not. It is not wrong if we ventured to touch the cable. We already know the risks of action were we to touch the wires. Yes, the risk of touching uninsulated wires are we going to sting, if it turns out electrified cable. If we are wrong in holding the cable, then the risk is the worst we die stung. In many cases of electric shock, the case is because the cable is still in the hands.

If we want to test electricity without tools, safe way or the best way is to use our left hand. That's because according to Art Margolis in his book entitled Electrical Wiring, page 56 states that, the flow of electric shock on our body:

- Electric shock through the right hand will be channeled towards our left foot, and the electricity will pass through our heart, causing vebrilasi ventriculasi.

- Electric shock through the left hand will be channeled towards our right foot, and electricity does not pass through our heart so it does not happen vebrilasi ventriculasi.

Vebrilasi ventriculasi is the designation for the disruption of the heart rate due to electric shock that occurs in the human body in a certain period. In addition to using the left hand, we must also use the back of our palms. That's because the human body has an iron content in their blood. We know that the electricity it has its own magnetic field. So if iron were met with a magnet, will take place the name magnetic attraction to the iron. So from that sense, we can find out why people were electrocuted when a cable holding will likely not be able to disconnect the cable from the clutch. The reason is why we have to check or test the cable with the back of our hands are our hands because the joints can not veer toward the back of the palm of our hands.

That is the explanation of the "Easy Way On Cable Without Knowing Electric Tools". The conclusion is that if we do not have the tools and we want to find out electricity in the cable then use the back of your hand and use the palm of his left hand. It was intended that we can minimize the risk of electric shock. Congratulations practice, and do not forget to always follow this article from the web. Comments are building indispensable writer in order to improve the quality of articles in the future. Thanks and greetings from writer to reader.

How To Make a Image Head of Engineering Drawing (Stuklis).

In the world of design, especially the design of the electrical installation planning and design planning of buildings used by the planner must be the name of the identity in the picture. Identity is often include a lot of things, and to put a name or indicate the identity resides in stuklis or can be called by the head of the image. Stuklis or the head of this image contains data relating to the engineering drawings. The data referred to here is like the title of the image, image maker name, and so forth.

In the world of electro, a designer or a technical drawing designer must be familiar with stuklis. Stuklis has two types, namely type A and type B. What is the difference of the two types is that? The difference is in the use and also in the manufacture of its size. To stuklis type A is usually used in the paper-sized A1 to A5. While stuklis type B, used in paper size A0 to A3. Stuklis or the head of this image is usually placed in the corner of the paper. Whether it's lower right corner, bottom left corner, the upper corner of the right and left upper corner, it's up to the creator of the image. But the most frequently used or most frequently drawn is stuklis Near the bottom right corner.

In terms of size, both types stuklis this difference is significant. To stuklis type A has a gauge width of 28 millimeters and 185 millimeters long. As for stuklis type B has a size of 75 millimeters wide and 190 millimeters long. In general, both types stuklis It contains the title picture, agency name, image scaling, image creation date, date of inspection images, draftsman name, date approved, information paper size, and number of images. The following pictures of stuklis :

Stuklis type A.

title picture			INFORMATION
			A3	No:
Name of Institution / School	SCALE:	IN PICTURES:
	EXAMINED:	APPROVED:	Section / Name draftsman

the size of each section :

- Title picture, width of 14 millimeters and length 130 millimeters.

- INFORMATION, 7 millimeters wide and 55 millimeters long.

- Paper size (A3), 14 millimeters wide, 15 millimeters long.

- Number picture (No: ), 14 millimeters wide, 40 millimeters long.

- Name of Institution / School, 14 millimeters wide, 60 millimeters long.

- SCALE, IN PICTURES, EXAMINED, APPROVED, 7 millimeters wide, 35 millimeters long.

- Section / Name draftsman, 7 millimeters wide, 55 millimeters long.

Stuklis type B.

SCALE:	DATE	Information:
IN PICTURES:	a.n
EXAMINED:	a.n
APPROVED:	a.n
Title picture
Name of Institution / School			A3	No:
			Section / Name draftsman

the size of each section :

- SCALE, IN PICTURES, EXAMINED, APPROVED, 7 millimeters wide, 70 millimeters long.

- DATE, 7 millimeters wide, 25 millimeters long.

- Information, 28 millimeters wide, 95 millimeters long.

- Title picture, width of 22 millimeters, 190 millimeters long.

- Name of Institution / School, a width of 25 millimeters, length 115 millimeters.

- Paper size (A3), 18 millimeters wide, 25 millimeters long.

- Number picture (No: ), 18 millimeters wide, 50 millimeters long.

- Section / Name draftsman, 7 millimeters wide, 75 millimeters long.