Bi-directional battery holder

A battery holder for axial-type dry cells, alkaline or other, has opposed faces for abutting either terminal of the battery and supporting two conductors, a center conductor contacting only the positive terminal of the battery and a flanking outer conductor contacting only the negative terminal of the battery depending on which terminal of the battery abuts the inner face. Center conductors are joined by a wire as are the flanking outer conductors so that the battery provides a single polarity of voltage through the wires regardless of the direction of its insertion within the battery holder. The center conductor is recessed within a groove to stabilize the battery and to prevent shorting of the different conductors by the battery terminals.

FIELD OF THE INVENTION 
This invention relates to battery holders that provide electrical 
connection to axial-type dry cell and alkaline batteries commonly 
identified as `AA`, `AAA`, `C`, or `D` type batteries, and in particular, 
to a battery holder that permits the battery to be inserted in either of 
two directions without loss of power or reversal of polarity of the 
voltage supply. 
Background of the Invention 
The carbon-zinc dry cell, employing a cathode mix of manganese dioxide and 
a zinc anode, achieved early popularity as a cylindrical package in which 
a central carbon electrode, in the form of a rod, was surrounded by the 
cathode mix and held within a cylindrical zinc can. The bottom of the zinc 
can, abutting a generally planar disk of metal, formed the negative 
terminal of the cell and one end of the central carbon rod, capped by a 
metal button whose inner surface grasped the carbon rod, formed the 
positive terminal of the cell. The resulting two battery terminals were 
thus at opposite bases of the cylindrical package and generally aligned in 
along the axis of the cylindrical package. 
This package, which will henceforth be termed "axial", now finds use in a 
number of different types of cells other than the zinc carbon cell, 
including alkaline as well nickel cadmium and lithium cells. Such axial 
cells come in a variety of sizes typically designated by different letters 
of the alphabet (e.g. AA, A, C, and D) and which differ in either or both 
of diameter and height. Each of these axial cells shares the 
characteristic that the positive terminal includes a centrally protruding 
button whereas the negative terminal has a substantially planar surface 
extending by a diameter substantially greater than that of the button. 
In technical usage, a battery is more than one electrochemical cell in a 
package, however, the term "battery" as used henceforth, should be 
understood to include either multiple or single cells per common usage. 
An early use of axial batteries was in flashlights. Here, ensuring the 
proper polarity of the installed batteries is of little concern. If the 
batteries are installed incorrectly, so that the light does not operate, 
the simplicity of the device makes the source of the problem evident. 
There is little risk of reversed batteries damaging the flashlight. 
In contrast, present day low-powered integrated circuits are extremely 
sensitive to the polarity of the applied voltage. Even a momentary 
reversal of polarity (reverse biasing), caused by a reversed connection of 
the batteries for example, can destroy such devices. When complex or 
expensive electronic equipment is battery powered, any possibility of the 
equipment being subject to even an inadvertent reversal of supply voltage 
must be eliminated. 
For this reason, it is known to construct battery holders for axial 
batteries in which the battery holder's connector to the positive terminal 
of the battery is placed in a recess having a diameter substantially equal 
to that of the conductive button of the positive terminal of the battery. 
In this way, if the battery is installed "backwards" so that its negative 
terminal is, in fact, adjacent to the positive connector of the battery 
holder, no contact will be made because the terminal of the battery will 
be too big to fit within the recess and make contact with the recessed 
connector. 
Unfortunately, although the battery holder protects the circuit from 
reverse biasing, no power is provided to the circuit when the batteries 
are installed backwards. In devices that do not visually or audibly 
indicate that they are receiving power, the failure of the device to 
operate because of incorrectly installed batteries may not be detected 
until too late. This is particularly unacceptable in cases where the 
battery operated device is a patient monitoring device that must work 
reliably to ensure capture of life threatening arrhythmias, for example. 
Human errors in inserting batteries incorrectly in such cases are likely 
because of the reduced alertness of the patient. The use of a pilot light 
or the like may not be practical because it may significantly decrease the 
operating life of the batteries. 
Even if the failure of the battery powered equipment to operate is readily 
recognized, the complexity of the equipment may lead the user of the 
equipment to the conclusion that the circuitry itself has malfunctioned, 
leading to wasted effort in diagnosing and servicing the equipment. 
It is possible to provide a single polarity of supply voltage to a circuit, 
regardless of direction in which the batteries are installed, by using a 
diode bridge. However, a diode bridge introduces a significant voltage 
drop between the batteries and the circuit that may be unacceptable for 
low voltage circuits using one or two cells. Voltage drop across 
protection diodes also result in significant reduction of the useful 
battery life. 
Importantly, if multiple batteries are used, diode bridges cannot 
practically correct for the situation where only some of the batteries are 
installed backwards. 
SUMMARY OF THE INVENTION 
The present invention provides a simple battery holder for axial type 
batteries that provides a single polarity of electrical voltage to 
attached circuitry regardless of the direction in which the batteries are 
inserted. 
Specifically, the holder includes a frame having contact plates attached at 
either end to present opposed faces separated by the length of the 
battery. An axial type battery having a conductive button on one terminal 
and a planar plate on the other terminal, may fit between the opposed 
faces so that its terminals are next to the opposed faces. A first and 
second conductor are exposed, one on each opposed face, to contact the 
conductive button of the battery, if the button is adjacent to a face. A 
third and fourth conductor, insulated from the first and second conductor, 
are exposed, one on each face and aside either the first and second 
conductor, to extend further from opposed faces than the first or second 
conductors and to contact the conductive plate of the battery, if the 
conductive plate is adjacent to a face. 
Thus, it is one object of the invention to eliminate the need for the user 
of a battery powered product to determine the proper direction for the 
insertion of any axial-type cell. The symmetrical arrangement of the 
electrodes on either face make the direction of insertion irrelevant. The 
displacement of the first and second electrodes with respect to the second 
and third electrodes insures that the first and second electrodes will 
only be contacted by the protruding button conductor of the battery while 
the third and fourth electrodes will preferentially contact the conductive 
plate of the negative terminal of the battery. 
The first and second conductors may be joined to provide a first polarity 
of electrical voltage and the third and fourth conductors may be joined to 
provide a second and opposite polarity of electrical voltage. 
It is another object of the invention to provide a single polarity of 
voltage regardless of the insertion direction of the axial-type cell 
without the need for diodes which introduce voltage drops limiting the 
available voltage from the inserted cells. Connecting the conductors as 
described provides points of constant polarity voltage regardless of the 
insertion direction of the battery. 
Accordingly, it is a further object of the invention to provide a battery 
holder that not only prevents an incorrect insertion of an axial-type cell 
from damaging sensitive circuitry but also that insures that such 
incorrect insertion does not simply block electrical flow from the battery 
to the circuitry such as might lead a user to conclude that the circuitry 
was not functioning. 
The opposed faces may include recesses sized to admit the conductive button 
of the battery but not the conductive plate and the first and second 
conductors may be placed within the recesses. 
It is thus another object of the invention to provide a means of aligning 
the cell within the battery holder to prevent shorting between the first 
and second conductors and the third and fourth conductors by the flat 
negative conductor of the battery. 
The foregoing and other objects and advantages of the invention will appear 
from the following description. In the description, reference is made to 
the accompanying drawings which form a part hereof and in which there is 
shown by way of illustration, a preferred embodiment of the invention. 
Such embodiment does not necessarily represent the full scope of the 
invention, however, and reference must be made therefore to the claims 
herein for interpreting the scope of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring to FIG. 1, a battery holder 10 of the present invention may 
receive an axial-type battery 12. 
As described above, such axial-type batteries 12 are generally cylindrical 
and have a positive battery terminal 14 and negative battery terminal 16 
opposed along the battery's axis at the two bases of a cylinder forming 
the body of the battery 12. The negative battery terminal 16 is generally 
a planar conductive plate of radius nearly equal to that of the body of 
the battery 12 whereas the positive battery terminal 14 includes a 
conductive button 18 having a radius substantially less than that of the 
body of the battery 12. The conductive button 18 is centered about the 
axis of the battery 12 and protrudes from the end of the battery 12 by a 
distance 15. 
The battery holder 10 includes a frame 20 extending longitudinally by 
substantially the length of body of the battery 12 between its terminals 
14 and 16. The frame 20 is terminated at its longitudinal ends by a first 
and second contact plate 22 extending transversely upward from the frame 
20. The frame 20 and the contact plates 22 are preferably molded from a 
nonconductive plastic or the like. 
At least one of the contact plates 22 is attached to the frame 20 by means 
of leaf springs 23 (to be described below) and that provide axial force on 
the battery 12 to hold battery 12 in position and that provide good 
electrical connection between contact plates 22 and battery terminals 14 
and 16. 
The height of the contact plates 22 and their separation along the frame 20 
is such as to define a battery space that will receive the battery 12 with 
the positive terminal 14 adjacent to the inner face of one contact plate 
22 and the negative terminal 16 adjacent to the inner face of the other 
contact plate 22. The battery 12 will fit within the battery space in 
either of two positions differing from each other only by a rotation of 
the axis of the battery by 180.degree.. 
The inner faces of the contact plates 22 incorporate rectangular slots 24 
extending transversely along the inner faces of the contact plates 22 
upward from the frame 20 so as to provide passage for the conductive 
button 18 of the battery 12 when the battery 12 is inserted into the 
battery holder 10 in either of the two positions. 
An electrical conductor 26 fits within each rectangular slot 24 so that the 
conductor 26 abuts that vertical surface of each slot 24 generally 
parallel to the inner face of the contact plates 22. The conductors 26, so 
positioned, may contact only the conductive button 18 of the positive 
terminal 14 when that button is received with the slot 24 associated with 
that conductor 26. 
Flanking the slots 24, and abutting the inner face of each contact plate 22 
are further conductors 28, electrically isolated from conductors 26, which 
contact only the planar negative terminal 16 of the battery 12 when the 
battery 12 is in position within the battery holder 10. The conductors 28 
for one contact plate 22 bend at right angles at their lower end to attach 
to the frame 20 and to form the leaf springs 23 providing the axial 
biasing of the contact plate as described above. 
Referring now to FIGS. 1 and 3, the longitudinal depth of the slot 24, and 
the longitudinal offset of the conductors 26 from the conductors 28 on 
each contact plate 22, is such that the distance 15 of the conductive 
button 18 holds the remainder of the positive battery terminal 14 away 
from the conductors 28 which otherwise would touch the outer rim of the 
positive battery terminal. This prevents a possible shorting of conductors 
26 to conductors 28. 
Thus, when the positive terminal 14 of the battery is near a first contact 
plate 22, the conductive button 18 will contact conductor 26 of the 
contact plate 22 and conductors 28 of that contact plate 22 will be held 
away from the terminal 14 by the physical extent of the conductive button 
18. On the other hand, the negative terminal 16 having no conductive 
button 18 will contact the conductors 28 at the other contact plate 22, 
but conductor 26 of that contact plate 22 will not touch the negative 
terminal 16 because it is recessed within the slot 24. If the battery 12 
is reversed in position with the positions of the negative and positive 
terminals 16 and 14 exchanged, the mirror symmetry of the conductors 28 
and 26 and slots 24 will provide that the conductive button 18 will 
contact the conductor 26 on the other contact plate 22 and the planar 
negative terminal 16 will contact the conductors 28 at the other contact 
plate 22. 
Conductors 28 on both contact plates 22 are connected together via a wire 
30 which provides a negative polarity of electrical voltage to any 
attached equipment. Likewise, conductors 26 on both contact plates 22 are 
connected together by a wire 32 which provides a positive polarity of 
electrical voltage to the attached equipment. 
It will be understood, therefore, that no position of battery 12 in the 
battery holder 10 will allow wire 32 to provide a negative polarity of 
voltage or wire 30 to provide positive polarity of voltage such as would 
reverse bias attached circuitry. Further, in both positions of the battery 
12 within the battery holder 10, electrical voltage will be present on 
wires 30 and 32. 
Thus the present invention avoids the problem of polarized battery holders 
that do not provide any electrical power if the battery is inserted in the 
wrong direction. Importantly, this ability of the present invention to 
supply power of the proper polarity when the battery 12 is in either of 
two positions, requires no commutation diodes and thus creates no wasteful 
voltage drop. 
Referring now to FIG. 1 and 5, the restraining friction between the 
conductors 28 and 26 and the respective terminals 14 and 16 of the battery 
may be increased, and electrical contact ensured, by mounting at least one 
of the contact plates 22 with leaf springs 23 so that a slight flexure of 
the leaf springs allowing outward longitudinal movements of the contact 
plates 22 is required for the insertion of the battery 12 within the 
battery holder 10. This provides a compressive force on the battery 12 by 
the battery holder 10 when the battery 12 is in place. 
This flexure may be accommodated and the alignment of the battery 12 within 
the frame 20 ensured by the addition of side flanges 36 extending 
longitudinally along either side of the frame 20 between the contact 
plates 22 to enclose the battery 12 within a rectangular, four sided tray. 
The height of the side flanges 36 may be reduced near the center of the 
frame 20 so as to permit easy removal and insertion of the battery 12 when 
grasped near its middle. 
The side flanges 36 may be integrally molded with the frame 20 and one of 
the contact plates 22 so that the spring mounted contact plate 22 is 
unattached to the side flanges 36 ensuring free flexure of the leaf 
springs 23 providing the desired compression of the battery 12 between the 
contact plates 22. 
Referring to FIGS. 4a and 4b the contact plates 22 may be shaped so as to 
permit either transverse or axial insertion of the battery 12. As shown in 
FIG. 4a, conductor 28 is formed in a "U" shape to surround the conductor 
26 on three sides and to permit axial motion of the button 18 of the 
battery (not shown) in between the arms of the "U". As shown in FIG. 4b, 
the conductor 28 is a square with a central circular opening centered on a 
disk-shaped exposed area of conductor 26. Here the button 18 of the 
battery 12 must be inserted axially and the contact plate 22 flexed 
outward by a sufficient amount to permit such axial insertion. 
Referring now to FIGS. 6 and 7 the invention provides important advantages 
in battery holders receiving multiple batteries. A two battery holder 10' 
holding a first battery 12 and a second battery 12' may be fashioned 
according to the above teachings by joining two of the battery holders 10 
of FIGS. 1 or 5, along their longitudinal edges. In the case where the 
side flanges 36 of FIG. 5 are employed, a center flange 37 may be 
substituted for the side flanges 36 at the joined edge, the center flange 
37 being substantially equal in dimension to side flanges 36 but somewhat 
shortened so as to not interfere with flexure of the contact plates 22 
toward each other. 
Electrically the conductors 26 and 28 associated with the first battery 12 
and the conductors 26' and 28' associated with the battery 12' are joined 
together as before. That is conductors 28' are joined together, conductors 
26' are joined together, conductors 28 are joined together, and conductors 
26 are joined together. Conductors 28 and 28', and 26 and 26', however, 
are not necessarily joined together, but rather, if a series connection of 
the batteries 12 and 12' is desired, as shown in FIG. 7, conductors 28' 
are connected to conductors 26 by a wire 40, conductors 26' are connected 
to a positive lead 44 providing voltage to the attached circuit, and 
conductors 28 are connected to a negative lead 42 providing voltage to the 
circuit. 
If parallel connection of the batteries 12 and 12' is desired, conductors 
28 and 28, are joined to the negative lead 42 and conductors 26 and 26' 
are joined together by the positive lead. There is no conductor 40 in this 
case. 
In either case, the battery holder of the present invention, connected as 
described, will accommodate any combination of insertion directions of the 
batteries 12 and 12' while still ensuring that the same voltage amplitude 
will be supplied to the attached circuitry and that the same polarity of 
voltage will be supplied to the attached circuitry. For two batteries 12 
and 12' there are four possible ways to install the batteries within the 
holder 10' all of which provide the same voltage. In contrast, only one of 
the four combinations will work in a conventional multi-battery battery 
holder. 
This above described concept may be readily expanded to more than two 
batteries with correspondingly increased benefits. For example, with a 
four battery battery holder there will be sixteen different possible ways 
of installing the batteries. The present invention allows each of these 
combinations to work. 
While this invention has been described with reference to particular 
embodiments and examples, other modifications and variations, such as 
application to projection reconstruction imaging techniques, will occur to 
those skilled in the art in view of the above teachings. Accordingly, the 
present invention is not limited to the preferred embodiment described 
herein, but is instead defined in the following claims.