The Automobile Storage Battery - BestLightNovel.com
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Willard Separators
Fig. 290 shows the Willard Threaded Rubber Separator which is made of a rubber sheet pierced by thousands of threads which are designed to make the separator porous. This separator is not injured by allowing it to become dry, and makes it possible for the Willard Company to s.h.i.+p its batteries fully a.s.sembled without electrolyte or moisture, the parts being "bone-dry."
[Fig. 290 Willard threaded rubber separator]
UNIVERSAL BATTERIES
Types. The Universal Battery Co. manufactures batteries for (a) Starting and Lighting, (b) Lighting, (c) Ignition, (d) Radio, (e) Electric Cars and Trucks, (f) Isolated, or Farm Lighting Plants, and (g) General Stationary Work.
Construction Features. The Universal Starting and Lighting Batteries embody no special or unique constructions. The boxes are made of hard maple, lock cornered and glued. The jars have single rubber covers.
The separators are made of Port Orford white cedar wood, this wood being the same as that used in some of the other standard makes of batteries. The s.p.a.ce between the covers and connectors is sufficient to permit lifting the battery by grasping the connectors.
[Fig. 291 Universal Battery Cover cross section]
Fig. 291 shows the Universal Co. Post Seal construction. A soft rubber washer (A) is first slipped over the post. The cover (B) is then put in place, and rests on the washer (A) as shown. A second washer (C) is then slipped over the post, resting on the upper surface of the shoulder of the cover. The lead sleeve washer (D) is then forced down over the post, pressing washer (C) down on the cover, and pressing the cover down on washer (A). The two rubber washers serve to make a leak proof joint between post and cover. The lead sleeve-washer (D) "freezes" to the post, and holds cover and washers in position.
In rebuilding Universal batteries the cover need not be removed unless it is desired to replace plate groups. To remove the cover, after the cell connectors have been drilled off, drill down through the post-stub until the drill has penetrated to the shoulder (E). This releases the seal and the cover may be lifted off. To save time, the post-stub may be cut off flush with the top of the cover with a hack saw after the cell connectors have been drilled off. The drill is then used as before to release the grip of the washer. Using a drill to release the grip of the washer makes it necessary to build up the posts when the battery is rea.s.sembled. Instead of using an ordinary twist drill, a special hollow drill may be obtained from the Universal Battery Co. This drill cuts away the lead sleeve gasket without injuring the post. If an ordinary drill is used, a 3/4 inch drill is required for the seven plate battery and a 13/16 inch drill for all other sizes.
ONE-PIECE BATTERY CONTAINERS
The standard practice in battery a.s.sembly has always been to place the plates of each cell in a separate, hard rubber jar, the jars being set in a wooden box or case. Each six-volt battery thus has four containers. When a wooden case is used, jars made of rubber, or some other nonporous, acid-resisting material are necessary.
[Fig. 292 One-piece battery container]
Wooden cases have been fairly well standardized as to the kinds of wood used, dimensions, constructional features, and to a certain extent, the handles. The disadvantage of both the wooden case and the iron handles is that they are not acid proof. Acid-proof paint protects them from the action of the acid to a certain extent, but paint is easily sc.r.a.ped off, exposing the wood and iron to the action of the acid. It is practically impossible to prevent acid from reaching the case and handles, and corroded handles and rotted cases are quite common.
A recent development is a one-piece container which takes the place of the jars and wooden case. Such a container is made of hard rubber or a composition of impregnated fibre which uses a small amount of rubber as a binder. These cases are, of course, entirely acid proof, and eliminate the possibility of having acid soaked and acid rotted cases.
Painting of cases is also eliminated. The handles are often integral parts of the case, as shown in Fig. 292, being made of the same material as the case.
The repairman should not overlook the possibilities of the one-piece containers. In making up rental batteries, or in replacing old cases, the one-piece containers may be used to advantage. These containers are suitable for Radio batteries, since they have a neater appearance than the wooden cases, and are not as likely to damage floors or furnis.h.i.+ngs because the acid cannot seep through them.
THE t.i.tAN BATTERY
The t.i.tan Battery is built along standard lines, as far as cases, plates, separators, and jars are concerned. The ribs of the grids not arranged at right angles but are arranged as shown in Fig. 293. Each pellet of active material is supported by a diagonal rib on the opposite face of the grid.
[Fig. 293a t.i.tan Battery grid]
[Fig. 293b t.i.tan Post Seal construction]
The t.i.tan Post Seal is shown in Fig. 293. A soft rubber gasket (G) is slipped over the post, and rests on a shoulder (F) on the post. The cover has a channel which fits over the gasket and prevents the gasket from being squeezed out of place when the cover is forced down on the gasket. The post has two projections (DD), as shown, the lower surface of each of which is inclined at an angle to the horizontal. A lock nut (H), which has corresponding projections (IJ) is slipped over the post as shown at (0), and is given a quarter turn. The top surfaces of the projections on the lock-nut are inclined and as the locknut is turned, the projections on the post and nut engage, and the cover is forced down on the gasket (G). To lock the nut in place, a lock washer (L) is then slipped over the post, the projections (MM) fitting into s.p.a.ces (KK) between the projections on the post and nut, thus preventing the nut from turning. A special wrench is furnished for turning the lock-nut. The cell connectors rest on the tops of the lock washers and keep them in place.
The overhauling of t.i.tan batteries should be done as described on pages 328 to 374.
SECTION 3.
CHAPTER 17.
FARM LIGHTING BATTERIES SPECIAL INSTRUCTIONS.
Although the large Central Station Companies are continually extending their power lines, and are enlarging the territory served by them, yet there are many places where such service is not available. To meet the demand for electrical power in these places, small but complete generating plants have been produced by a number of manufacturers.
These plants consist of an electrical generator, an engine, to drive the generator, and a storage battery to supply power when the generator is not running. The complete plants are called "House Lighting," "Farm Lighting," or "Isolated" plants.
The batteries used in these plants differ considerably from the starting batteries used on automobiles. The starting battery is called upon to deliver very heavy currents for short intervals. On the car the battery is always being charged when the car is running at a moderate speed or over. The battery must fit in the limited s.p.a.ce provided for it on the car, and must not lose any electrolyte as the car jolts along over the road. It is subjected to both high and low temperatures; and is generally on a car whose owner often does not know that his car has such a thing as a battery until his starting motor some day fails to turn over the engine. All starting batteries have wooden cases (some now use rubber cases), hard rubber jars, and sealed on covers. The case contains all the cells of the battery.
Automobile batteries have, therefore, become highly standardized, and to the uninformed, one make looks just like any other.
Farm lighting batteries, on the other hand, are not limited as to s.p.a.ce they occupy, are not subjected to irregular charging and discharging, do not need leak proof covers, and are not called upon to delivery very heavy currents for short periods. These facts are taken advantage of by the manufacturers, who have designed their farm lighting batteries to give a much longer life than is possible in the automobile battery. As a result the farm lighting battery differs from the automobile battery in a number of respects.
Jars. Both gla.s.s and rubber are used for farm lighting battery jars, and they may or may not have sealed-in covers. Fig. 294 shows a gla.s.s jar of an Exide battery having a hard rubber cover, and Fig. 295 shows a Prest-O-Lite gla.s.s jar cell having a cover made of lead and antimony. Unsealed gla.s.s jars, such as the Exide type shown in Fig.
324, generally have a plate of gla.s.s placed across the top to catch acid spray when the cell is ga.s.sing. Each jar with its plates and electrolyte forms a complete and separate unit which may easily be disconnected from the other cells of the battery by removing the bolts which join them. In working on a farm lighting battery, the repairman, therefore, works with individual cells instead of the battery as a whole, as is done with automobile batteries.
[Fig. 294 Exide "Delco Light" farming lighting cell with hard rubber cover]
Batteries with sealed jars are generally s.h.i.+pped completely a.s.sembled and filled with electrolyte, and need only a freshening charge before being put into service, just as automobile batteries which are s.h.i.+pped "wet" are in a fully charged condition when they leave the factory and need only a charge before being installed on the car.
[Fig. 295 Prest-O-Lite farm lighting cell with lead-antimony cover]
Jars that are not sealed are set in separate gla.s.s trays filled with sand, or sometimes the entire battery is set in a shallow wooden box or tray filled with sand. This is necessary because the absence of a sealed cover allows acid spray to run down the outside of the jar and this acid would, of course, attack the wooden shelf and make a dirty, sloppy battery. Batteries using jars without sealed covers cannot be s.h.i.+pped a.s.sembled and charged, and hence they require a considerable amount of work and along initial charge to put them in a serviceable condition.
[Fig. 296 Exide farm lighting cell with sealed gla.s.s jar]
Farm lighting battery jars are less liable to become cracked than those of automobile batteries because they are set in one place and remain there, and are not jolted about as automobile batteries are.
Cracked jars in farm lighting batteries are more easily detected as the jar will be wet on the outside and the acid will wet the shelf or sand tray on which the jar rests.
Batteries with sealed rubber jars are normally a.s.sembled four cells in a case or tray, with a nameplate on each tray which gives the type and size of cell. The cells are connected together with lead links which are bolted to the cell posts by means of lead covered bolt connectors.
[Fig. 297 Combination wood and rubber separator used in Delco-Light and Exide Farm light cell]
Plates. Since farm lighting batteries are not required to deliver very heavy currents at any time, the plates are made thicker than in starting batteries, this giving a stronger plate which has a longer life than the starting battery plate.
All makes of starting batteries use the Faure, or pasted plate. This type of plate is also used in many farm lighting batteries, but the Plante plate (see page 27) may also be used. The Exide "Chloride Acc.u.mulator" cell, Fig. 323 uses a type of positive plate called the "Manchester" positive as described on page 497.
Separators. Grooved wooden separators are used in some farm lighting batteries, while others use rubber separators, or both rubber and wooden separators. Some use wooden separators which are smooth on both sides, but have dowels pinned to them.
Electrolyte. In a starting battery the specific gravity of the electrolyte of a fully charged cell is 1.280-1.300, no matter what the make of the battery may be. In farm lighting batteries, the different types have different values of specific gravity when fully charged.
The usual values are as follows:
(a) Batteries with sealed gla.s.s jars 1.210 to 1.250