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Building Materials




Submerged Arc Welding

Types of Welding

Non – consumable Electrode Arc welding

As a non – consumable electrodes tungsten or carbon electrodes can be used. In gas-tungsten arc welding a tungsten electrode is used in place of the metal electrode used in shielded metal-arc welding. A chemically inert gas, such as argon, helium, or carbon dioxide is used to shield the metal from oxidation. The

heat from the arc formed between the electrode and the metal melts the edges of the metal. Metal for the weld may be added by placing a bare wire in the arc or the point of the weld. This process can be used with nearly all metals and produces a high – quality weld. However, the rate of welding is considerably slower than in other processes.

Shielded Metal Arc weldingIn shielded metal-arc welding, a metallic electrode, which conducts electricity, is coated with flux and connected to a source of electric current. The metal to be welded is connected to the other end of the same source of current. An electric arc is formed by touching the tip of the electrode to the metal and then drawing it away. The intense heat of the arc melts both parts to be welded and the point of the metal electrode, which supplies filler metal for the weld. This process is used mainly for welding steels.

Gas –metal Arc weldingIn gas-metal welding, a bare electrode is shielded from the air by surrounding it with argon or carbon dioxide gas and sometimes by coating the electrode with flux. The electrode is fed into the electric arc, and melts off in droplets that enter the liquid metal of the weld seam. Most metals can be joined by this process.

 

Submerged-arc welding is similar to gas- metal arc welding, but in this process no gas is used to shield the weld. Instead of that, the arc and tip of the wire are submerged beneath a layer of granular, fusible material that covers the weld seam. This process is also called electroslag welding. It is efficient but can be used only with steels.

The mortars used in bricklayers’ work consist of an admixture of lime, or Portland cement, and sand. A knowledge of the properties of these materials is very necessary t the craftsman, if he is to obtain the best results from his labours.

Lime is manufactured by the calcination, or burning, of a carbonate of calcium, of which chalk is the commonest example. During calcination, decomposition occurs, and carbonic acid and water are driven off, an oxide of calcium (quicklime) remaining. If water be addedd to lumps of quicklime, rapid combination ensues, great heat and volumes of steam being generated. The lumps disintegrate with a series of small explosions, and are eventually reduced to a very fine powder. This process is termed slaking; and when making mortar it is highly necessary that it should be thoroughly carried out, as any unslaked particles subsequently expand and seriously damage the work. Limes may be divided into three distinct classes - Rich limes.

2. Poor limes.

3. Hydraulic limes.

Rich limes contain not more than 6 percent of impurities, slake very rapidly, and are entirely dependent on the external agents for setting power. They are chiefly used for interior plasters’ work. Poor limes contain from 15 percent to 30 percent of useless impurities, and possess the general properties of rich limes, only to a lesser decree. They are only fit for unimportant work. Hydraulic limes contain certain proportions of impurities, which, during calcination, combine with the lime, and endow it with the valuable property of setting under water, or without external agents. The proportions of these impurities determine whether a lime is eminently, moderately, or only feebly hydraulic. The principal limes used in making mortar for constructional work are of the Greystone variety. These have hydraulic properties, and will take a large proportion of sand, without weakening their setting powers. The usual proportions are from two to four parts of sand to one lime. The setting of lime depends largely upon its absorption of carbonic acid from the atmosphere. The particles return to their original form of a carbonate, and crystallize. The crystals have a tendency to adhere to anything rough, such as sand or the surfaces of a brick. Pure lime mortars built into thick walls never harden in the interior. The crystallization of the exterior of the joint when set prevents access of carbon dioxide to the inside of the wall. For this reason, pure lime mortars should not be used for constructional work, only those which are not entirely dependent on external agents. For more important work, where great strength is required, Portland cement is used instead of lime. Portland Cement is an artificial cement, manufactured by calcining chalk and clay, or river mud containing certain chemical constituents in definite proportions. The chalk and clay are ground and mixed into a slurry, which after being strained through very fine sieves, is pumped into an orifice in the top of an inclined revolving cylinder. A blast of intense flame is directed through this cylinder, which is lined with firebrick. As the slurry drops through the flame, it is burned into small clinkers, which are afterwards ground exceedingly fine in specially constructed mills, and then passed through sieves, having as many as 35,000 meshes to the square inch. The powder is aerated by being spread on wooden floors, with an occasional turning, to ensure the thorough slaking and cooling of all particles. It is then put up in sacks ready to use.

This process of aeration has now been superseded in many cement works by the addition of small quantity of gypsum (plaster of Paris), which retards the otherwise rapid – setting tendency of a freshly – ground cement. Sand. – When used for mortar, sand should be angular in grain, free from clay or dirt, and moderately coarse. If too fine, the proportion of lime or cement will have to be considerably increased. Mixing. – This should be carried out on a close – boarded platform, or stage, and the heap opened out into the form of a ring. The correct proportion of lime is measured into the ring, clean water being added to start the slaking, and more as the process advanced. When the generation of steam ceases, the mass should be stirred with a long – handled, hoe – shaped tool called a larry, until a thick, cream – like consistency is obtained. The sand may then be gradually drawn into and thoroughly mixed with the lime by means of the same tool. The mortar should be allowed to stand for some days before use and again well beaten up with larry and shovel.

For cement mortar, the sand is measured and heaped on the stage, and bottomless box of definite capacity is placed on the top of the sand. This box is filled with cement, and then removed. The dry heap is turned over at least twice and opened out into a ring. Clean water is added in sufficient quantity to wet the whole mass, which is then thoroughly mixed in the same manner as lime mortar. Cement mortar should be used directly after being made, and should not be subjected to the further mixing after setting has commenced. If this is done, the cement rapidly loses its strength, and further repetition would render it practically inert. The proportions of sand and cement or lime, are from two to four parts of sand to one part of either, according to the class of work for which the mortar is required. Another mortar mix which is becoming popular, and which some engineers have proved to be stronger for some classes of work such as reinforced brickwork, is 4 parts of sand to 1 part of Portland cement and 1/8th part of lime. On large works, mixing is usually performed in a mortar mill, which consists of a pair of a pair of heavy millstones and a pan, or container into which the measured ingredients are fed. The mill, by reason of its large and rapid output, has a distinct advantage over hand – mixing. It also has many disadvantages unless operated by a reliable man. Grinding may be carried on to such a stage that the sand is ground so fine as to render the original quantity of lime or cement inadequate. Cement mortars may be also ground long after the initial setting has commenced, and thus rendered useless for the required purpose.

 

Notes:

admixture - суміш

cement – цемент

lime – вапно

oxide – окис

lump – грудка

to ensure – виникати, випливати

to slake – гасити (вапно)

hydraulic – гідравлічний

impurity – бруд

constituent – складова

sieve – решето, сито

exceedingly- надзвичайно

to supersede – заміняти

to retard – затримувати

consistency – послідовність

to reinforce - підсилювати




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