High Paying Welding Jobs - 3 Things You Absolutely Must Do to Get High a Paying Welding Job

Want a high paying welding job? Do these 3 things:

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Get really good by practice and experience. Be able to pass a welding certification test by learning welding tips and tricks and good welding fundamentals. Learn how to toot your own horn without sounding arrogant.

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Sounds simple right? well let me break it down a bit for you because each one of these statements deserves a whole page of explanation.

Get really good by practice and experience.

Aircraft Pilots have to acquire a certain amount of "seat time" to achieve certain ratings. In welding, nothing takes the place of "seat time". Have you ever heard the saying "you cant teach experience"? But seat time and practice are not much good if you don't have someone to show you the right way. So Find a good welding instructor and school and approach learning to weld like it was your job. Then get some experience. For your first job, take the welding job that offers the best experience even if the pay is less than other jobs that wont teach you as much. Later, after you are experienced, you will be in a better position to negotiate pay.

Be able to pass a welding certification test

Whether you just finished welding school or are already an experienced welder, you still have to pass a welding certification test to get the really high paying welding jobs. Sometimes welding tests don't even resemble the skills you need in the field or in the shop. So What? It is what it is and you have to be able to pass the test before you can get that high paying welding job. The best advice I can give anyone is to talk to the person giving the welding test and find out the details of the test. If its a pipe welding test, there are literally hundreds of different tests it could be. Size of the pipe, wall thickness, joint configuration, process, material type, and electrode type are just some of the variables. Most of the time the test shop supervisor will tell you the details of the test. Once you have that, find a school that will let you practice on the exact test you will be taking. Don't be afraid to invest a little coin here. It might cost you a couple hundred dollars but you could easily get that back in a week or two after landing that high paying welding job.

Learn how to toot your own horn without sounding arrogant.

Tooting your own horn is a real skill. Most people go too far in one direction. They either brag, or try to appear humble and miss out on an opportunity to sell themselves. Use your resume to peak curiosity. Make factual statements like "maintained a 99% acceptable x-rate rate for 4 years on stainless steel piping systems for borated water". Statements like that that are factual will prompt questions. That is your opportunity to simply explain the details and obstacles you had to overcome in order to achieve the results. Saying something like "I can weld anything from a broken heart to the crack of dawn" Will only serve to make you appear unprofessional. You might get a chuckle out of the interviewer but they will secretly be thinking "Awh, Bless his heart". NEXT Please!

High Paying Welding Jobs - 3 Things You Absolutely Must Do to Get High a Paying Welding Job
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Atoms and Molecules

The idea of the atom

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Models and mechanisms of how particles and other materials behave have been proposed for thousands of years. Especially in the last few centuries, however, these models have been constantly improved and specified. In the following chapters, a cross section of these developments will be presented, leading all the way to our present model of the atom, which will be explained along with all of the laws that govern its behaviour.

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The first model of matter which included elements and atoms was proposed in ancient times. The Greek philosopher Leukippos (around 500-400 B.C.) and his student Democritus (around 460-370 B.C.) were the first to describe the matter present in our world as a collection of atoms (Greek: indivisible). Their theory was based on the idea that if any body is divided into its smallest constituent parts, at some point the parts are so small that they can no longer be divided. They used the word indivisible to describe this remaining matter. According to this theory, atoms are small bodies which are not able to be divided.

Atoms of different materials must differ in their composition and size. The characteristics of materials must therefore be determined by differences in their individual atoms: differences in their size, grouping and mutual arrangement. At the beginning of the 19th century, the Greek atomic model was expanded upon and specified by J. Dalton (1766-1844). According to his theory, elements are composed of small particles called atoms

Atoms of individual materials differ in their mass and size. During chemical reactions, atoms themselves remain unchanged. Of course, the number and position of individual atoms in the reactant compounds can and does change. They are combined in certain proportions, only to change those combinations and proportions during a reaction. In more advanced atomic models, atoms are composed of a nucleus and electrons.

The atom, of course, is composed of elementary particles. In an atom's nucleus are neutrons (uncharged) and positively charged protons. Atoms of the same element always contain the same amount of protons. Only the number of neutrons can differ slightly (in isotopes). Isotopes are actually different atoms of the same element differing only in the number of neutrons they contain and their atomic weight. Otherwise, isotopes of one element generally have the same chemical and physical characteristics as the element itself.

The average atomic nucleus is relatively small compared to the atom itself, but it makes up the greatest part of an atom's mass. The mass of protons and neutrons has been designated with the relative number 1. The number of protons in an atom determines its atomic number. This number is also used to symbolize the atom, or element, in the periodic table of the elements. (hydrogen (H)=1, Helium (He)=2, etc.). Electrons (negatively charged particles) revolve around the nucleus of an atom in electronic orbitals, designated areas where they can be found. Their mass is relatively small - 1/1836 the mass of protons and neutrons. There is the same amount of electrons as the number of protons in the nucleus. For this reason, every atom, in its natural state, is neutral.

Atoms can lose one or more of their electrons. When they do, they become positively charged. Or, atoms can gain electrons, which makes them negatively charged. When an atom gains or loses electrons, it is called an ion. The outer reaches of an atom, its shell, away from the inner nucleus and where electrons are found, makes up the greatest part of its size. This area is mostly empty space. Electrons move in certain designated areas around the atomic nucleus. Some electrons are closer to the nucleus than others (inner orbital, or shielded electrons). Others are further away from the nucleus (outer orbital electrons).

The nucleus of an atom does not change during a chemical reaction. For this reason, it does not appear to be very important. Of course, an atom's electrons determine its chemical behaviour (mostly these are outer orbital electrons).

The energy of a specific electron is defined with the help of both letters and numbers, according to the orbital where the electron is found. Of great importance is an electron's distance from the nucleus. The exact placement of an atom's electrons at any one time is impossible to determine, because location and direction of an individual electron are not able to be calculated (The Heisenberg Uncertainty Principle).

The more accurately we try to determine the location of a specific electron, the less accurate is our ability to determine its direction. Why? Because it is impossible to tell which direction that electron will move in the moment we have determined its location. Unfortunately, only the probability of where an electron might be found can be calculated. On the other hand, if we know the direction an electron is moving, its exact location becomes impossible to locate. The spacial limitation, more simply the area where an electron of a certain energy can be found with greatest probability, is called the atomic orbital.

Duality

Because atoms and their electrons cannot be directly investigated, reality at the atomic level is more or less unknown. From atomic characteristics which can be observed, however, atomic models can be made. The accuracy of these models is seen in their ability to explain certain phenomena. Often, these incredibly small particles show characteristics that are not usual in the macro world we live in. Electrons themselves are capable of a certain principle of duality - as is light: the duality of waves and particles. This means that on the one hand, an electron can behave as a sort of particle beam, a bit like a ray gun. On the other hand, electrons also show a purely wave-like character. Electrons are not, however, one or the other, because these two characteristics are contradictory. Yet we need both concepts to be able to describe an electron's behaviour. The wave-like mechanical atomic model comes from the description of the outer shell of an atom and the wave-like characteristics of electrons.

Quantum numbers

In the atomic model of Niels Bohr (Danish physicist), an electron cloud swarms around the nucleus of an atom. Electrons are allowed to move only in certain orbitals around the nucleus. The individual orbitals represent a certain amount of energy. All of the electrons in one orbital are seen as containing the same amount of energy.

The energy of an electron is given by a quantum number n. The larger this number is, the more energy an electron contains, and the further away it is from the nucleus.

When an electron is excited to a more distant orbital from the nucleus, one with a higher energy, a certain energy must be added to the electron (a quantum). When an electron moves from a higher energy orbital to a lower energy orbital, closer to the nucleus, energy must be omitted in the form of radiation (heat, light or in the form of a different type of electromagnetic energy. With the help of the main quantum number, we are able to figure the maximum number of electrons in the outer shell of an atom.

The number of an atom's electrons can be calculated using the formula 2n2, where n is the main quantum number. More recent atomic models use other quantum numbers to describe an atom and its electrons. A secondary quantum number, designated as l, represents the spin of an electron, or its angular momentum. That means its geometric spatial orientation. This quantity is decisively important in order to explain the arrangement of certain chemical bonds in the atoms of a compound.

The energy of a specific electron is defined mainly by the main quantum number n, and to a lesser degree by its secondary quantum number l. From the position of the energy level of an electron, from its orbital (where the electron moves) compared to the outer magnetic field, the magnetic quantum number m (also called the direction quantum number) can be determined. According to the value of m, orbitals can be divided on the basis of their energy.

There is one s orbital (spherical symmetrically placed around the nucleus), three p orbitals (which look like three dumb-bells protruding from the nucleus in their centers and and pointing out in three directions), five d orbitals (four-leaf structures lying between the p orbitals) and seven f orbitals. Within the individual types (s, p, d, f) are individual orbitals of the same energy. If we take the electron to be a small particle, we can imagine it to be spinning on its own axis, to the left or to the right. The direction of its rotation is termed its spin, and is determined by the quantum number s, for spin. With the help of these four quantum numbers, each and every electron can be exactly described.

Stable electron orbitals

The assignment of electrons to their individual orbitals is termed electron configuration. According to the Pauli principle (Swiss-American physicist), no more than two electrons can be found in one orbital at one specific time.

Orbitals are occupied by electrons from lowest energy orbital to highest energy orbital (in the order s, p, d, f). First of all, every orbital of a specific energy is occupied by one electron. Then, an orbital of opposite spin moves into an orbital to join the first electron. Once there are two electrons in one orbital, it is filled completely. The two electrons are called an electron pair. Individual electrons are called unpaired electrons. In each element of the main group, all s and p orbitals are filled gradually, as electrons are added. For the elements of other groups, the d orbitals are filled.

Ionisation energy

Electrons have a certain amount of energy associated with them, and this energy determines their distance from the nucleus. If energy is added to an electron, an electron can increase its distance from the nucleus, or can even escape from the nucleus. In the latter case, an atom becomes a positively charged ion. The amount of energy which is necessary for an electron to leave the atom is called its ionization energy. Therefore, the ionisation energy necessary to free an electron in an outer orbital from an atom is less than for an electron which is closer to the nucleus.

The density of an element is a relative number given by how the matter of an element is arranged around its atoms, on average. The density of different elements can only be compared given the same volume. Density is a function of both mass and volume.

Density units are often given as kg/m3 or g/cm3. The densities of a number of materials are included in tables.

At first glance, many elements share a number of characteristics. A closer comparison of those characteristics, including colour, state of matter (solid, liquid, gas), odour, flammability and density, allow substances to be distinguished one from another. When substances' characteristics are compared and contrasted, they can be divided into groups. The most important groups that chemistry deals with are: acids, bases, oxides, salts, metals, hydrocarbons and polymers (materials with a great number of atoms which repeat their patterns in a periodic way.

Molecules and Moles

The smallest possible chemical unity is formed by the union of a number of atoms - a compound - also called a molecule. If we want to produce a certain amount of a material, we choose whether to produce that certain amount as a function of its mass, volume or even amount of individual particles.

In chemistry, we use the variable (n) very often as a measure of the amount of a certain substance. One unit of a material is called a mole. We can imagine this amount of a substance as a chemical dozen, an even unit, so to speak. And just like a dozen, or 12, one mole is always equal to a certain number of particles. Of course, this number is more than 12, because of the minute size of atoms and molecules. It would indeed be difficult to count in multiples of 12.

One mole is given as 6.022 x 10 23 particles. This seemingly arbitrary amount of particles is actually based on a chemical truth, using carbon (chemical symbol C), because this element plays one of, if not the, most important role in chemistry. Twelve grams (g) of the element carbon contains exactly 1 mole of atoms. Why is the number of smallest particles so important in chemistry? The answer to this question has to do with the nature and types of chemical reactions. During a chemical reaction, particles interact with one another, often combining to form a new substance. For example, water is actually the combination, or a compound, of two atoms, two atoms of hydrogen and one atom of oxygen. The mass of the two reacting elements would not be enough to ensure a sufficient amount of each element for combination, because oxygen atoms are significantly heavier than hydrogen atoms.

In the laboratory, a chemist cannot determine the amount of a substance by deduction, or by some type of instinct. The amount of a substance can, however, be determined by its mass, which directly relates to the amount of particles a certain amount of substance contains. The quotient of a certain amount of mass (m) and an amount of substance (n) is given by the molar mass (M), with the unit number of grams per one mole.

Molar mass is determined by the sum of the masses of the individual atoms in a molecule. Atomic masses are easily attainable, from the periodic table of the elements. (Hydrogen (H) 1g/mol, Helium (He) 4 g/mol, Lithium (Li) 7g/mol, Beryllium (Be) 9 g/mol, etc.). See the periodic table for more atomic masses.

The molar mass of water (H2O) is 18 grams per mole: 1g/mol for each hydrogen atom (H) and 16 g/mol for the one oxygen atom (O). The molecule is composed of three atoms (2H + 1 O), or more simply: three parts, or atoms, join to make one larger compound, or molecule. The amount of particles corresponding to 1 mole of water is 6.022 . 10 23 molecules of water.

Individual atoms of each element have the same mass. The variable masses of individual molecules is a function of the bonding capabilities of those molecules' constituent atoms, and their atomic masses.

Matter, or mass, is neither created nor destroyed. If during a chemical reaction a compound, or other products of that reaction have less mass than the original reactant materials, most likely one of the products is not easily detectable - possibly an invisible, odourless gas, or some other byproduct of the reaction. If a scientist accurately compares the mass of all reactant materials with the mass of all products produced, the same amount is always present on both sides. Matter is neither created nor destroyed; it can only change form.

A mixture of a solid material dissolved in a liquid is called a solution. These mixtures can be measured by their volumes. The amount of a material dissolved in the same volume of a solution can vary from one mixture to another, however. To determine the amount of a dissolved substance in a solution, we use the chemical formula concentration (symbol: c), a measure of its variable "strength". The units of concentration of a solution are amount of moles dissolved in one litre of solution. Substance concentration is indicated as the concentration of a substance in solution. It is the quotient equal to the amount of a material dissolved in a certain volume of a solution (12 g of carbon (C) in one liter of water has a concentration of 1 mol/l). We call this amount of solution a one molar solution of carbon, and abbreviate it as 1 M.

In order to determine the molar concentration of a solution, or in the case that a chemist might need to prepare a solution of a given molar concentration, it is necessary to calculate the mass of each material. The mass of the dissolved substance is calculated from the necessary material mass and mass of one mole of the material. The amount of a substance in a solution can be calculated from the concentration of a substance and the volume of the solution.

For example, for a 1 molar solution of table salt we need 58.5 g of table salt in 1 l of water. Table salt is made of one part sodium and one part chlorine. The chemical formula of this compound is NaCl. The mass of one mole of NaCl is 58.5 g, because sodium (Na) has a molar mass of 23 g and chlorine (Cl) an atomic mass of 35.5 g. Add the two together (23 + 35.5 = 58.5). The mass of one mole is easily attainable from the periodic table of the elements.

A certain molar concentration does not tell how much volume a certain solution contains. That is, a 1 molar solution does not guarantee that there is 1 liter of solution. Rather, a 1 M solution implies that the ratio of dissolved substance (solute) to volume of substance dissolved in (solvent). In our example with table salt, then, rather than use 58.5 g of NaCl with 1 l of water, we could have just as easily used 29.25 g of NaCl with 0.5 l of water, or 117 g of salt with 2 l of water.

Chemical symbols

Substances and chemical reactions can be denoted in a simple and straightforward way in chemistry. A system of symbols, abbreviations and chemical formulas is used, and these are all internationally recognised - thanks to a committee of international experts who have agreed upon these symbols. At first, however, somewhat abstract symbols were used. Eventually, circular symbols to denote compounds were used. Today's system was introduced by J. J. Berzeliem (Swedish chemist 1779-1848). According to this system, each element was assigned a chemical symbol, usually taken from its Latin or Greek equivalent (for example Magnesium - Mg or oxygen = Oxygenium - O).

Elements are made up of small particles of one and only one kind. We call these particles atoms. In some elements, atoms combine in their natural state, in twos or even more, to form a compound of the given element. In this case, the atoms of one element are joined tightly together, thereby attaining an increased chemical stability. We call these combinations molecules and molecular substances. Molecules are often the smallest building blocks of

gaseous or fluid substances. For example, atoms of hydrogen, nitrogen and oxygen are always joined together, in pairs, two each. There are molecules, however, that are made of different elements. The compound " water " is made of one atom of oxygen and two atoms of hydrogen.

One important foundation of chemical terminology is the concept of using small numbers after a chemical element symbol to indicate number of atoms, called stoichiometry. In the language of chemical symbols, an element symbol is often combined with these numbers, and is called a chemical formula. A formula, then, is made up of the element symbols that a certain compound is composed of. And, after each element symbol, the number of atoms of that element contained in the compound is given. This number is smaller than the element symbol. Ones, as in one atom of an element, are understood, and therefore not written, as in the chemical formula of water, H2O, understood as two atoms of hydrogen, and one atom of oxygen. Water is therefore not written as H2O1.

The formula of a compound characterises the material it represents and denotes its constituent elements, the elements it is made of. At the level of individual particles, the formula symbolises the molecule and gives the amount of all atoms in the molecule, and their ratio to one another. The ratio of the number of individual atoms in a molecule can be calculated for example with the help of the mass ratio of the individual elements and their atomic masses.

Stoichiometry says that the atoms in a compound are mutually bonded in unchanging ratios.

1. Dalton's law: The ratio of the masses of two elements which are bonded together in one molecule can be given as the ratio of one whole number to another.

2. The law of definite proportions: Every compound contains elements in a certain specific and constant mass ratio.

3 The law of consistent proportions: Elements combine together in certain specific ratios of masses or in whole number amounts.

How many atoms of one element join together with how many atoms of another element can be determined by experiment and calculation. The true chemical formula of a number of compounds can be determined rather simply, however, if we know the bonding possibilities of individual elements (their valence). This is the deciding factor for individual elements. For example, once we know the bonding possibilities of an element, we can figure out quickly how many hydrogen atoms could conceivably bond to it. The valence of an element when bonding with hydrogen is given by the amount of unpaired electrons in the outer shell of its electron cloud (the cloud made up of electrons moving at certain levels or in certain orbitals around the nucleus). For example: in water (H2O) one oxygen atom (O) bonds with two hydrogen atoms (H) and therefore has a valence of 2.

In chemical bonds, elements, or their atoms, are not only joined in whole numbers, but their mass ratios also remain constant. For example, in the chemical reaction of iron (Fe) se sulfur (S) iron sulfide (FeS) is formed. The ratio of the number of individual atoms is 1:1. The ratio of masses of the individual atoms is determined from the atomic masses of sulphur and iron, and is 1.45 (7:4).

Atoms and Molecules
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Power Drills Buyer's Guide

Take the hard work out of DO-IT-YOURSELF with a good drill.
It could be on of the most diverse and very useful tools you buy.
Proper drill will save time during your work and make easy drilling holes into metal, wood, concrete etc., as well as drive screws and bolts.
It is useful getting acquaint with a drill's main feature before you buy, so you could choose the best one.

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I. Types
Standard Drills Hammer Drills Screw Guns
II. Cordless drills

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Cord or Cordless? Pros and Cons The main features Power and Battery
III. Drill Shapes
IV. Variable speed
V. Torque
VI. Other features to look out for
VII. Power rating
VIII. Hammer action
IX. Chuck type

TYPES

Standard Drills

Standard electric rotary drills designed for drilling metal and wood. This type of drill is normally small and compact. Motor sizes range from around 500 watts. The lower wattage motors are ok for drilling small holes or minimal use, the more powerful motored machines will cope with larger size holes and more frequent use. The chuck size is another thing to check, the smaller drills have a chuck which will only accept drill bits up to 10mm diameter the larger chuck size is 13mm.

Hammer Drills

The hammer drill is similar to a standard electric drill, with the exception that it is provided with a hammer action for drilling masonry. The hammer action may be engaged or disengaged as required.

The hammer action is cheap but delicate. It uses two cam plates to make the chuck accelerate towards the work. However because of the relative masses of the chuck+bit and the remainder of the drill the energy transfer is inefficient and will fail to penetrate harder materials and vibrates the operators hand. The cams wear quickly.

Compare this to a rotary/pneumatic hammer drill where just the bit is accelerated to the work. They have relatively little vibration and penetrate most building materials. It feels as though the work is sucking the bit inwards.

Large cam hammer drills, especially transverse motor, are crude in their action. The energy delivered in each stroke is highly variable. The cheaper drill will smash its way through the work and vibrate the surroundings, this can cause lots of collateral damage. A good SDS drill will gently pulverize the work material just in front of the bit and glide into the hole without any "fuss".

However there is a big difference in cost. In the UK typically £12-40 for a cam hammer and £100 up for a rotary/pneumatic. For light DIY use they are fine.

Screw Guns

These Electric Screwdrivers are made specifically for applying screws and hexagon headed Tek Screw to plasterboard and metal cladding. The drywall screws are designed purely for plasterboard fixing. The electric screwdriver uses a specially designed chuck to self guide the specifically designed fixings that feature widely spaced threads to ensure good grip. This is achieved by the unique collar on this type of electric screwdriver.

Some electric screwdrivers are able to use Collated Screws which provides auto-loading of screws which are loaded into the tool on a strip which is then fed onto the bit.

Drill press

A drill press (also known as pedestal drill, pillar drill, or bench drill) is a fixed style of drill that may be mounted on a stand or bolted to the floor or workbench. A drill press consists of a base, column (or pillar), table, spindle (or quill), and drill head, usually driven by an induction motor. The head has a set of handles (usually 3) radiating from a central hub that, when turned, move the spindle and chuck vertically, parallel to the axis of the column. The table can be adjusted vertically and is generally moved by a rack and pinion; however, some older models rely on the operator to lift and re-clamp the table in position. The table may also be offset from the spindle's axis and in some cases rotated to a position perpendicular to the column. The size of a drill press is typically measured in terms of swing. Swing is defined as twice the throat distance, which is the distance from the center of the spindle to the closest edge of the pillar. For example, a 16-inch drill press will have an 8-inch throat distance.

A drill press has a number of advantages over a hand-held drill:

less effort is required to apply the drill to the workpiece. The movement of the chuck and spindle is by a lever working on a rack and pinion, which gives the operator considerable mechanical advantage.

the table allows a vise or clamp to position and lock the work in place making the operation secure.
the angle of the spindle is fixed in relation to the table, allowing holes to be drilled accurately and repetitively.

Speed change is achieved by manually moving a belt across a stepped pulley arrangement. Some drill presses add a third stepped pulley to increase the speed range. Modern drill presses can, however, use a variable-speed motor in conjunction with the stepped-pulley system; a few older drill presses, on the other hand, have a sort of traction-based continuously variable transmission for wide ranges of chuck speeds instead, which can be changed while the machine is running.

CORDLESS DRILLS

A cordless drill is a type of electric drill which uses rechargeable batteries. These drills are available with similar features to an AC mains-powered drill. They are available in the hammer drill configuration and most also have a clutch setting which allows them to be used for driving screws.

For continuous use, a worker will have one or more spare battery packs charging while drilling, so that he or she can quickly swap them, instead of having to wait several hours during recharges.

Early cordless drills started with interchangeable 7.2V battery packs, and over the years the battery voltage has been increased to 18V, and higher, allowing these tools to produce as much torque as many mains-powered drills. The drawback of most current models is the use of nickel-cadmium (NiCd) batteries, which develop a memory effect or internal short circuits due to dendrite growth, severely limiting their useful life, and posing a hazardous materials disposal problem. Drill manufacturers are now introducing lithium ion batteries, most notably DEWALT.

The main advantages are lack of memory effect and very short charging time. Instead of charging a tool for an hour to get 20 minutes of use, 20 minutes of charge can run the tool for an hour. Lithium-ion batteries also have a constant discharge rate. The power output remains constant until the battery is depleted, something that nickel-cadmium batteries also lack, and which makes the tool much more versatile. Lithium-ion batteries also hold a charge for a significantly longer time than nickel-cadmium batteries, about 2 years if not used, vs. around 4 months for a nickel-cadmium battery.

CORD OR CORDLESS. Pros and Cons

I. Corded Drills
Pack the most power Most durable Can handle mixing mud, boring holes, and drilling concrete Usually unnecessary for most homeowners
II. Cordless Power Drills
Easily transported and used Less power and run time restricted by battery life Recharging may take several hours Higher voltage means more power, but also more weight Newer technology has improved cordless drills; most are now strong enough for many tasks previously out of their league
Cordless drill:

Corded drill:

THE MAIN FEATURES

Top 10 points to look for:

Speed-range switch, generally 2 ratios, both high and low, normally selected by changing mechanical gearing. High is for drilling applications whilst low range is reserved for driving screws. Look out for the widest range between the two settings

Look for a reliable motor, some models have external brushes for easy changing - when the brushes wear down you can easily change them for new ones, some bosch models have this feature ,it is only of use if you are uning your cordless drill on a daily basis.

Forward/reverse switch: This should be easy to operate with either your thumb or trigger finger - again this is a standard feature but look for one which is easy to operate.
Hand grip: Texture and contoured, should aid your grip, some Porter and Cable cordless drills have padded grips which you can choose to match your hand size - useful after an 8 hour shift.

Voltage: a higher voltage means more drilling power but it can also mean more weight - don't buy a drill you won't need, 12 volt drills are powerful enough for most DIY users, bigger models just weigh more so think carefully about what you will be using the drill for.

Batteries: Two are better than one. New NiMH batteries tend to be better because they deliver more charge and last longer.

Trigger: Make sure your index finger fits around it comfortably when gripping the drill, Variable speed offers the greatest control.

Chuck jaws: The maximum chuck capacity on most drills is 3/8 inches. Although some 14.4 and 18V drills can handle 1/2-inch-diameter bits, these have a 1/2inch chuck.

Keyless chuck: Virtually a standard fitting today, hand-turn it to open and close the chuck jaws. The keyless chuck can grip any screwdriver bit or drill bit securely.

Clutch: Setting the clutch gives you greater control of the depth to which screws are driven.

POWER AND BATTERY

Batteries: A cordless drill is only as good as its battery. Make sure the battery has enough run time to help you power through all your tasks. For more demanding applications, look for a drill that comes with a second battery or purchase an additional one. Chargers can take several hours to fully recharge a battery, so bear that in mind when planning your work schedule. If you need a faster recharge, look for a "smart" charger. Smart chargers work quickly and often reduce charge as the battery becomes full to avoid overcharging to extend the life of the battery. Look for nickel-metal-hydride (NiMH) and lithium-ion batteries, as they are slightly smaller and tend to have a longer run time.

Charge a second battery as you work to avoid mid-job downtime

Smart chargers use fans to reduce heat and decrease recharging time

NiMH batteries are easier and less hazardous to dispose of than other types

First thing when you look at a good cordless drill will be Volts of the the battery pack. To simplify it - the more Volts your cordless drill has - the faster the motor spins - the more torque you will get. Unfortunately - the more volts your cordless drills have - the heavier they get (if you ever worked with a 18 Volt drill over a longer period of time - you will know what I am talking about).

Similar important as the Volts of your battery are the Ampere. Measured in Ah (Ampere per hour) it gives you an idea of how long a battery will last. You can have a 12 Volts battery with 1.8 Ah and with 2.4 Ah. Obviously both batteries should give you the same power initially, but the 2.4 Ah will last 30% longer. Important if you use cordless drills for heavy duty work.

Looking at Volts and Ampere, you should also understand the basic types of battery packs currently available on the market. The (older) Standard Nickel Cadmium (Ni-Cd) battery packs are cheaper but do not give you much Ah as the newer Nickel Metal Hydride (Ni-MH) battery packs. The Ni-MH packs also give you an additional advantage in recharging, as the do not loose power after being recharged many many times (no-memory effect). Nickel Metal Hydride (Ni-MH) battery packs are usually more expensive, but definitely worth it's money.

As batteries changed improved over the past years most manufacturers offer a wide range of power packs. Finding the right Dewalt or Makita batteries can therefore sometimes be a bit of a challenge.

The higher the voltage, the more power (9.6-28V) and weight (3-10 lb) the drill will posess. Most household jobs will be fine with a 13.2 volt or 14.4 volt battery, but an 18 volt couldn't hurt. Most 9.6V drills might be sufficient for home jobs, but may lack the needed torque you find in a 14.4V drill -- which is usually not significantly more in price. Go with at least a 14.4V. For tough jobs and doing masonry, a more powerful 24 or 28 volt battery is recommended.

Rechargeable drill batteries should last you about five years, or roughly 500 charges, though with frequent use you might need to replace it sooner. They can be pricey (-) so if your drill was only 0 or less, you might want to consider just buying a brand new drill. If you have a higher end drill, it's probably more economical to buy a replacement battery.

DRILL SHAPES

Pistol Grip Drills

Are held like a pistol.

Doesn't that feel powerful?

T-Handle Drills

Are most popular.

Shaped like a T for best balance.

Right Angle Drills

Are barrel-less.

The bit extends from the base at a right angle.

TORQUE

Drill price reflects a number of features, including torque. Torque, which is measured in foot-pounds, is the drill's maximum amount of turning force. Some drills have an adjustable clutch with different torque settings for different applications.

Common features you'll want in a cordless or corded drill are electric brakes, which stops the drill chuck as soon as you release the trigger, and keyless chucks.

OTHER FEATURES TO LOOK OUT FOR

Keyless Chuck: The chuck holds the drill bit in place, and keyless chucks allow you to conveniently change bits without having to use a separate key to unlock and replace.

Auxiliary Handle: Drills with side handles provide greater control and two-handed operation. These auxiliary handles rotate, enabling you to find the ideal angle and position from which to work.

Multiple Clutch Settings: Cordless drills often feature a clutch adjustment ring, which may have anywhere from two to twenty-four settings. Once you know the depth and torque needed on a particular surface, set the clutch accordingly to ensure consistent results and reduce the instance of wrist snap.

Electronic Brake: This feature causes the drill to stop immediately when you stop squeezing the trigger, preventing you from overdriving or stripping screws.

Variable Speed and Reversing: Many drills offer multiple speed settings, allowing you to choose the right one for the job at hand, and most have a reverse feature that allows you to remove screws and other fasteners.

Heat Shields and Cooling Fans: These features protect the drill from overheating, enabling longer, more efficient periods of use.

Power Drills Buyer's Guide
Variable Heat Gun

Special Price!!! Wagner Power Products HT3000 Variable Temperature Heat Gun with Turbo Cool

Wagner Power Products HT3000 Variable Temperature Heat Gun with Turbo Cool
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Wagner Power Products HT3000 Variable Temperature Heat Gun with Turbo Cool

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Wagner Power Products HT3000 Variable Temperature Heat Gun with Turbo Cool Feature

  • Variable temperature setting of 220 degrees F to 1100 degrees F
  • TurboCool setting cools nozzle in 1/10 the time
  • Can be used for anything from paint removal to thawing frozen pipes
  • Accessories includes three concentrator tips, a scraper, and a steel brush
  • Two year home use warranty


Wagner Power Products HT3000 Variable Temperature Heat Gun with Turbo Cool Overview

The HT 3000 variable heat settings of 220 degrees to 1100 degrees F enhance the versatility of uses of this 1200 watt, 10 amp heat gun. Higher settings are ideal for paint removal or thawing of pipes while the lower settings are ideal for bending and shaVariable temperature setting of 220 degrees F to 1100 degrees FTurboCool setting cools nozzle in 1/10 the timeCan be used for anything from paint removal to thawing frozen pipesAccessories includes three concentrator tips, a scraper, and a steel brushTwo year home use warranty



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Milwaukee 8975-6 11.6 Amp 570/1000-Degree Fahrenheit Dual Temperature Heat Gun

Special Price!!! Milwaukee 8975-6 11.6 Amp 570/1000-Degree Fahrenheit Dual Temperature Heat Gun

Milwaukee 8975-6 11.6 Amp 570/1000-Degree Fahrenheit Dual Temperature Heat Gun
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Milwaukee 8975-6 11.6 Amp 570/1000-Degree Fahrenheit Dual Temperature Heat Gun

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Milwaukee 8975-6 11.6 Amp 570/1000-Degree Fahrenheit Dual Temperature Heat Gun Feature

  • Dual temperature 570 and 1000-degrees F; 11.6 amp motor
  • Unique impact resistant heating element
  • Efficient soft air velocity-increases surface temperature much faster than conventional hot air heat guns
  • Three position rocker switch - off, high and low
  • Limited warranty, 30-day no-risk trial


Milwaukee 8975-6 11.6 Amp 570/1000-Degree Fahrenheit Dual Temperature Heat Gun Overview

8975-6 Model Code: AC - Price is for 1 Each (part# 8975-6) This item features: -Impact resistant heating element. -Soft air velocity: Reaches required working surface temperature faster then conventional heat guns. -Maintains temperature for fast completion of work. -Cool air inlet design. -Support stand. -For various applications from forming and molding plastic, thawing pipes, shrink fit plastic, and other applications that require a heat source. -Rear housing rotates to select temperature. -Voltage: 120.00 VAC. -Frequency: 60.0 Hz. -Amps: 11.60 A. -Flow: 14.8 CFM. -Length: 10 1/8 in. -Type: Heat Gun. -Wt.: 1.60 lb. Testing and approvals: -Complies with OSHA and UL requirements. Model Code  Model Description AAOperating Temp.:140 F [Min], 1040 F [Max], Control Type:On/Off - 2 Temperatures ABOperating Temp.:140 F [Min], 1040 F [Max], Control Type:On/Off - 2 Temperatures, Includes:Accessory Assortment 49-80-0300, Impact Resistant Carrying Case ACOperating Temp.:570 F [Min], 1000 F [Max], Control Type:On/Off - 2 Temperatures, On/Off Speed ADOperating Temp.:570 F [Min], 1000 F [Max], Control Type:On/Off - 2 Temperatures, On/Off Speed, Includes:Accessory Assortment 49-80-0300, Impact Resistant Carrying Case



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Grizzly H0801 Heat Gun - 1800 Watt

Grizzly H0801 Heat Gun - 1800 Watt
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Grizzly H0801 Heat Gun - 1800 Watt

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Grizzly H0801 Heat Gun - 1800 Watt Overview

These two superb heat guns are very versatile. Both guns feature variable temperature control from 120-590 degrees C. The 1200 Watt model can handle most applications easily while the 1800 Watt model is more for heavy-duty, industrial use. Both are UL approved.



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What Is the Truth About Cell Phone Health Hazards Studies?

Mobile phones use electromagnetic radiation in the microwave range. Currently we have two opposing groups concerning cell phone health hazards. Number one group relies on studies funded by the telecom industry and number two group bases its results on independently funded research.

Variable Heat Gun

Guess which group says there are no health risks concerning the use of wireless phones? Number one. Group number two, as you may already have guessed, has found studies which have very disturbing health issues connected with cell phone health hazards..

Variable Heat Gun

I side with number two group because of the number of results I have found which show how many scientific studies have had their funding withdrawn after negative results were reported.

Rachael Carson was chastised when she raised the warning about DDT; Herbert Needleman when he warned us about lead poisoning in children; and Irving Selikoff when he warned us about the harmful effects of asbestos?

Why do we have to wait years to heed the warnings and take them seriously, after the damage is done and people's lives have been damaged? Why is hindsight always 20/20?

Besides the funding of the telecom industry influencing the research results, what other variables are skewing the research results concerning cell phone health hazards?

Number one,the World Health Organization and other governing bodies that regulate wireless communication technologies base their safety standards on the heating of skin tissue not on the actual heating of the brain...heating of the brain?

Remember electromagnetic radiation is within the microwave frequency. Think of the microwave oven that many of us use everyday. How does it work? Unlike putting a pot on to boil and heating from the outside, microwaves heat from the inside out. The brain has no sensory nerve endings to warn us that this heating is taking place.

On top of this, the structure of the head and brain is very complicated and is non-uniform, meaning changing in unpredictable ways. When these "hot spots" are produced with the heating of the brain they can vary by tens or hundreds of times compared to brain tissue nearby.

Think of it like this. Just like on a poorly made pot or skillet, hot spots can exist and the temperature can vary greatly from one spot to another and result in burning and under-cooking on the same surface. Hot spots in the brain have been found by cell phone radiation studies to be close to the surface of the skull, deep within the brain and also on a molecular level.

Number two, the Federal Communications Commission (FCC) regulates cell phones. With most new phones, a number called the Specific Rate Absorbtion (SAR) is included. This number is supposed to rate how energy (radiation) is absorbed by the brain. How is this number determined?

First an arbitrary assumption (number) is concocted out of thin air, representing the rate of safe release of added heat from the brain. The rate the FCC came up with was up to 1 degree C per hour. Using this mystery number a head made of plexi-glass and filled with a homogeneous (uniform) liquid is heated. Voila because the liquid is uniform, no hot spots are formed.

The problem with this is that reality exists. Our brains are not homogeneous but no-uniform and people use their cell phones for hours a day chronically heating spots in their brains. It probably won't come as a shock at this point, but process for determining SAR numbers was created by electrical engineers, not doctors.

Number three problem area, which is really the "smoking gun" concerning cell phone hazards, is damage which occurs to the blood-brain membrane, which protects the brain and lets nutrients pass from the blood to the brain and keeps toxins out.

Leif Salford, a Swedish neurosurgeon has been running different variations of one simple experiment since 1988. Young laboratory rats, which have the same blood-brain membrane as humans, are exposed to either cell phone radiation or microwave radiation and then sacrificed to look for albumin in their brain. Albumin is a protein normally existing in blood which is not supposed to cross over into the brain.

For 18 years his researchers have consistently found albumin in the brain tissue by exposing the rats to microwave radiation at doses equal to a cell phone's emission. A one-time exposure of two minutes resulted in a leak of albumin into their brain, meaning that blood vessels have been damaged and the membrane has compromised.

In 2003, another one of Salford's cell phone hazards research studies determined that a one time 2 hour cell phone exposure permanently damaged the membrane and destroyed 2% of the rat's brain in areas responsible for learning, memory and movement.

You don't have to be a research scientist to understand these results. What do you think? Are we the lab rats being experimented on now? What is happening to us and what can we do to protect ourselves?

What Is the Truth About Cell Phone Health Hazards Studies?
Variable Heat Gun

Milwaukee 8977-20 11.6 Amp Variable Temperature Heat Gun
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Milwaukee 8977-20 11.6 Amp Variable Temperature Heat Gun Feature

  • Perfect for use where flameless heat is required
  • Variable temperature, 140 to 1040-degrees
  • Powerful 11.6 Amp motor
  • Unique impact resistant heating element
  • Lightweight 1.6-pound design


Milwaukee 8977-20 11.6 Amp Variable Temperature Heat Gun Overview

This professional line of Heat Guns offer ergonomic style and powerful heating elements. With stay cool handles and heat shields, you can use these all day while you stay cool. The variable temperature adjustment allows you to dial in the proper temperature for you job.

Milwaukee 8977-20 11.6 Amp Variable Temperature Heat Gun Specifications

The Milwaukee 11.6 Amp Variable Temperature Heat Gun offers ergonomic style and powerful heating elements. With exclusive "stay-cool" handles and heat shields, the heat gun offers convenient all-day use. The heat gun's efficient soft air velocity increases surface temperature much faster than conventional hot air heat guns. The unit offers a 140- to 1040-degree temperature range, and the variable temperature adjustment allows you to precisely dial in the proper temperature. The heat gun weighs only 1.6-pounds, perfect for steady holding.

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Steinel 34103 SV 803, UltraHeat Variable Temperature Heat Gun, Without Case

Steinel 34103 SV 803, UltraHeat Variable Temperature Heat Gun, Without Case
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Steinel 34103 SV 803, UltraHeat Variable Temperature Heat Gun, Without Case Feature

  • Lightweight ergonomic design with soft grip handle, reduces user fatigue
  • Takes only a few seconds to charge, for quick use
  • 3 stage switch to regulate airflow
  • Up to 1050 degrees, wide temperature range for a variety of uses
  • For intermittent high temperatures


Steinel 34103 SV 803, UltraHeat Variable Temperature Heat Gun, Without Case Overview

The SV 803 UltraHeat Heat Gun Features Variable Temperature Control, Soft Grip Handle, 3 Stage Air Control, Cool, Low, High, Designed For General Purpose Intermittent Use, Temperature, Up To 1050 Degrees F, UL, C-UL Listed



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Milwaukee 8985 11.6 Amp 140/1040 Degree Fahrenheit Variable Temperature Heat Gun Kit

Milwaukee 8985 11.6 Amp 140/1040 Degree Fahrenheit Variable Temperature Heat Gun Kit
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Milwaukee 8985 11.6 Amp 140/1040 Degree Fahrenheit Variable Temperature Heat Gun Kit Feature

  • Variable temperature from 140- to 1040-degrees Fahrenheit; 11.6-amp motor
  • Unique impact resistant heating element
  • Efficient soft air velocity increases surface temperature much faster than conventional hot air heat guns
  • Rotate rear housing to select temperature
  • Limited warranty, 30-day no-risk trial


Milwaukee 8985 11.6 Amp 140/1040 Degree Fahrenheit Variable Temperature Heat Gun Kit Overview

This professional-quality heat gun offers ergonomic style and powerful heating elements. With stay cool handle and heat shield, you can use this heat gun all day while you stay cool. Complete kit includes a selection of nozzles and stores in an impact-resistant case. Volts: 120 AC, Amps: 11.6, Required CFM: 14.8, Heat Settings: Variable, Temperature Capacity (deg F): 140 - 1,040, Case Included: Yes



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Gun Safes and Home Safes - What You Need to Know Before Purchasing

Gun safes are like garages, it does not matter how big you get them, you always find yourself wanting more space. That's because the main reasons for owning a gun safe, theft protection and fire protection, apply to many other things in your home. The secure nature of a gun safe make them perfect for jewelry, documents, coin collections, and other storable valuables. The fire resistance of a Gun Safe make them perfect for storing family photos or heirlooms. When safe shopping think ahead to other things in your house that you or another family member may want to protect.

Variable Heat Gun

Most gun safes list their capacity by the number of guns they can hold. This number may be a variable based on the different interior options of the safe or a single number which usually is the most from all interior options. This number may be true if all your guns are slim such as shotguns or scopeless lever actions. Often times one scoped bolt action rifle will use the space the manufacturer allowed for two guns in the safe. (unless you are willing to jam guns together like a jigsaw puzzle) This is true for all gun safe makers so we suggest taking the manufacturers capacity and reducing it by a quarter to a third to get a "real world" capacity of a safe.

Variable Heat Gun

Often two safes of the same size and appearance will carry vastly different prices. The first reason for this difference is the amount of steel in the safe. Safes manufactured from thin steel and composites (two layers of thin steel sandwiching a fire resistant board) may appear solid and carry just a good fire rating as safes made from heavy gauge or plate steel. They will not, however, be as secure as their heavier counterparts and may be vulnerable to being "axed" open.
Pay attention to the listed weight of the safes you are examining. Weight can't be faked, plate steel safes will be far heavier then composite ones. You can also rap on the door with your knuckles, a composite door will have a "hollow" ring. Quality safes will also carry a UL listed label. To be listed the safe will have passed the Underwriters Laboratories test which consists of giving common burglary tools such as crowbars and drills to experienced safecrackers and giving them thirty minutes to enter the safe. If they enter the safe in that time period the safe fails.

The second reason similar looking safes may vary greatly in price is fire rating. More expensive safes usually carry better fire ratings. The fire rating is most often found on a label on the inside edge of the door. The rating will list two temperatures and a time. For example 1200 degrees, 30 minutes, 325 degrees. In this example the temperature the safe was exposed to was 1200 degrees and after 30 minutes of exposure the maximum recorded internal temperature was 325 degrees. No safe is truly fire proof, if exposed to fire temperatures for long enough the internal temperature of the safe will rise to equal the external temperature and any combustible valuables will be lost. However the nature of a house fire is to rise in temperature drastically and then fall off fairly quickly as nearby combustible material is consumed. Every fire pattern is different and there are never any guarantees but a safe with a better rating could well preserve its contents that would have been lost with a lesser safe.

There are two types of finishes found on gun safes. A textured paint finish or a glossy "car paint" type finish. The textured finishes are sprayed on in a single layer while it may take twenty or more layers of paint to achieve the smooth glossy "car paint" finish. The extra labor involved in building a glossy safe increases their cost at retail by up to several hundred dollars for a same sized safe.

Glossy finishes are most often selected for safes that will be on display in rooms such as living rooms or offices. They show dust and fingerprints very quickly so you will have to clean them regularly if you want them to look their best. Textured finish safes take much less care to look attractive.

If your safe will be in an unheated room or garage, or in an area of high humidity it is recommended that you install a dri-rod or use desiccant packs in your safe. The dri-rod is a small heater that installs on the inside of the safe. It provides a small amount of heat to the interior of the safe to keep rust and mildew off your guns and valuables. It is powered by electricity, a small hole is drilled in the safe near its bottom, (pre-drilled by manufacturer on most safes) just big enough for the electrical cord to pass through. Desiccant packs are large packs of silica gel that absorb moisture from the air. Over time they lose their effectiveness and will need to be replaced or dried in a oven.

A big part of protecting your valuables from rust and mildew is to keep moisture from entering the safe in the first place. Firearms wet from use in the field should be dried thoroughly before returning them to your safe. Anything else stored in the safe should also be dry before storage. If your safe is in an area that may be subject to flood or seepage install it raised off the floor high enough to be above any entering moisture.

Think carefully about your current and future needs when making your purchase. A gun or home safe is not an inexpensive investment, and once purchased it is likely to be with you for a long time.

Gun Safes and Home Safes - What You Need to Know Before Purchasing
Variable Heat Gun

Milwaukee 8985 11.6 Amp 140/1040 Degree Fahrenheit Variable Temperature Heat Gun Kit
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Milwaukee 8985 11.6 Amp 140/1040 Degree Fahrenheit Variable Temperature Heat Gun Kit Feature

  • Variable temperature from 140- to 1040-degrees Fahrenheit; 11.6-amp motor
  • Unique impact resistant heating element
  • Efficient soft air velocity increases surface temperature much faster than conventional hot air heat guns
  • Rotate rear housing to select temperature
  • Limited warranty, 30-day no-risk trial


Milwaukee 8985 11.6 Amp 140/1040 Degree Fahrenheit Variable Temperature Heat Gun Kit Overview

This professional-quality heat gun offers ergonomic style and powerful heating elements. With stay cool handle and heat shield, you can use this heat gun all day while you stay cool. Complete kit includes a selection of nozzles and stores in an impact-resistant case. Volts: 120 AC, Amps: 11.6, Required CFM: 14.8, Heat Settings: Variable, Temperature Capacity (deg F): 140 - 1,040, Case Included: Yes



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Milwaukee 8988-20 Variable Temperature Heat Gun

Milwaukee 8988-20 Variable Temperature Heat Gun
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Milwaukee 8988-20 Variable Temperature Heat Gun Feature

  • Ceramic encapsulated heating element for maximum tool life
  • LED Digital Readout Display shows present temperature in increments of 10º F
  • One hand operation with lightweight and easy grip handle
  • Upright stationary use with pads on back cap and lower handle
  • Limited warranty


Milwaukee 8988-20 Variable Temperature Heat Gun Overview

This variable temperature heat gun offers a range from 90 to 1050deg Fahrenheit. The LED digital readout display allows you to monitor the temperature via a digital display when precision control is needed. Three controlled air volumes, 7.06/8.83/15.89 cu.ft.min., allow you to match the air speed to your application. The first stage air volume does not include heat for cooling applications. Volts: 120 AC, Amps: 12.5, Required CFM: 7.06, 8.83, 15.89, Heat Settings: Variable, Temperature Capacity (deg F): 90 - 1,050, Case Included: No



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DEWALT D26950 Heat Gun

DEWALT D26950  Heat Gun
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DEWALT D26950 Heat Gun Feature

  • Variable temperature control allows for adjustment of the heat settings
  • Built-in overload protection shuts the heating element down and prevents burn up
  • Built-in hang ring adds a convenient storage feature
  • Built-in innovative kickstand support provides greater stability and prevents tip over
  • Cord Protector keeps the cord from tearing away from the housing Ergonomic comfort grip provides greater comfort for long hours of use


DEWALT D26950 Heat Gun Overview

13A heat gun with variable temperature control allows for adjustment of the heat settings. Built in overload protection shuts the heating element down and prevents burn up. Built in hang ring adds a convenient storage feature. Built in innovative kickstand support provides greater stability and prevents tip over. Cord protector keeps the cord from tearing away from the housing. Ergonomic comfort grip provides greater comfort for long hours of use. Separate internal components allows maintenance on both the motor and the heating element. Lightweight and compact design weighs only 2.1 lb.



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DEWALT D26950  Heat Gun

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