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Claims  |
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What is claimed is:
1. An electronic instrument which is supplied with electric power from a
battery, said instrument comprising:
a battery chamber for selectively receiving first and second batteries
which are different from each other in shape and output voltage, said
battery chamber including terminal means for providing the battery power
and a space which is commonly occupied by parts of said first and second
batteries;
means for determining the presence of said first or second battery received
in said battery chamber and generating a signal representing the result of
the determination;
an electronic circuit operative at a given supply voltage; and
a voltage converting means, connected between said terminal means of said
battery chamber and said electronic circuit, for converting the output
voltage of the battery to the given voltage in response to said signal.
2. The electronic instrument according to claim 1, wherein said electronic
circuit includes a high-power circuit operative at a first supply voltage
which is higher than either of the output voltages of said first or second
batteries, and said voltage converting means includes a first and second
DC-DC converter for respectively converting the output voltages of said
first and second batteries to said first voltage and a selecting means for
selectively activating said first and second DC--DC converter in response
to said signal.
3. The electronic instrument according to claim 1, wherein said electronic
circuit includes a low-power circuit operative at a second supply voltage
which is equal to the output voltage of said first battery and lower than
the output voltage of said second battery, and said voltage converting
means includes a voltage reducing circuit for reducing the output voltage
of said second battery to said second voltage, and reduction control means
operative in response to said signal for activating said voltage reducing
circuit with said second battery being received in said battery chamber,
and deactivating said voltage reducing circuit and directly supplying the
battery power to said electronic circuit with said first battery being
received in said battery chamber.
4. The electronic instrument according to claim 3, wherein said electronic
circuit further includes a second low-power circuit operative at a third
supply voltage which is between the output voltages of said first and
second batteries, and said voltage converting means further includes a
second voltage reducing circuit connected between said terminal means of
said battery chamber and said second low-power circuit for reducing the
output voltage of said second battery to said third voltage, said
reduction control means including means for activating said second voltage
reducing circuit with said second battery being received in said battery
chamber and deactivating said second voltage reducing circuit with said
first battery being received in said battery chamber.
5. The electronic instrument according to claim 1, wherein said means for
determining includes a projection means movable between a projecting
position where it projects into said battery chamber, and a retracted
position where it is retracted from said battery chamber, said projection
means being located at a position where it is engageable with only one of
said first and second batteries to be moved from said projecting position
to said retracted position.
6. The electronic instrument according to claim 1, wherein said battery
chamber includes a first receiving portion for receiving said first
battery and a second receiving portion formed as a recess at the bottom of
said first receiving portion for receiving said second battery in
cooperation with said first receiving portion.
7. The electronic instrument according to claim 6, wherein said terminal
means of said battery chamber includes positive and negative power source
terminals with which positive and negative electrodes of said first and
second batteries respectively commonly come into contact.
8. The electronic instrument according to claim 7, wherein said first
battery is a packaged battery of which positive and negative electrodes
are provided in the same plane and said second battery includes two
battery cells which are arranged side-by-side with respective positive and
negative electrodes being disposed at opposite ends of each of said two
battery cells.
9. The electronic instrument according to claim 8, wherein said second
battery has a cross-sectional area parallel to said electrode plane of
said first battery smaller than that of said first battery and a length
perpendicular to said battery plane longer than that of said first
battery.
10. The electronic instrument according to claim 9, wherein said second
receiving portion has a cross-sectional area equal to that of said second
battery and a depth equal to the difference between the lengths of said
first and second batteries.
11. The electronic instrument according to claim 10, wherein said means for
determining includes a projection means movable between a projecting
position where it projects into said second receiving portion and a
retracted position where it is retracted from said second receiving
portion.
12. The electronic instrument according to claim 11, wherein said means for
determining further includes means for urging said projection means toward
said projecting position.
13. An electronic instrument which is supplied with electric power from a
battery, said instrument comprising:
a battery chamber for selectively receiving first and second batteries
which are different from each other in shape and output voltage, said
battery chamber including terminal means for providing battery power and a
space which is commonly occupied by parts of said first and second
batteries;
means for determining the presence of said first or second battery received
in said battery chamber and generating a signal representing the result of
the determination;
an electronic circuit operative at a first supply voltage which is higher
than either of the output voltage of said first or second battery;
first and second DC-DC converter means connected between said terminal
means of said battery chamber and said electronic circuit for respectively
converting the output voltage of said first or second battery to said
first supply voltage; and
a selecting means for selectively activating said first or second DC-DC
converter in response to said signal.
14. The electronic instrument according to claim 13, wherein said
instrument includes a camera, said electronic circuit includes an
electronic flash circuit, and said first DC-DC converter includes primary
and secondary coils, said second DC-DC converter being constructed to
commonly use a part of said primary coil and all of said secondary coil of
said first DC-DC converter.
15. An electronic instrument which is supplied with electric power from a
battery, said instrument comprising:
a battery chamber for selectively receiving first and second batteries
which are different from each other in shape and output voltage, said
battery chamber including terminal means for providing battery power and a
space which is commonly occupied by parts of said first and second
batteries;
means for determining the presence of said first or second battery received
in said battery chamber and generating a signal representing the result of
said determination;
a first circuit operative at a first supply voltage which is equal to the
output voltage of said first battery and lower than the output voltage of
said second battery;
a second circuit operative at a second supply voltage which is between the
output voltages of said first and second batteries;
a first reducing circuit connected between said terminal means of said
battery chamber and said first circuit for reducing the output voltage of
said second battery to said first supply voltage;
a second reducing circuit connected between said terminal means of said
battery chamber and said second circuit for reducing the output voltage of
said second battery to said second supply voltage; and
a reduction control means operative in response to said signal for
activating said first and second reducing circuits with said second
battery being received in said battery chamber and deactivating said first
and second reducing circuits and directly supplying the battery power to
said first circuit with said first battery being received in said battery
chamber.
16. The electronic instrument according to claim 15, wherein said
instrument includes a camera, said first circuit includes an exposure
control circuit and said second circuit includes a film wind-up and
rewinding circuit.
17. The electronic instrument according to claim 16, wherein said first
circuit further includes a focus detecting circuit.
18. The electronic instrument according to claim 16, wherein said first
circuit further includes a data recording circuit.
19. A battery chamber for an electronic instrument which selectively
receives first and second batteries which are different from each other in
shape, said first battery having a first planar portion provided with both
positive and negative electrodes, said second battery having a
cross-sectional area parallel to said first planar portion smaller than
that of said first battery and a length perpendicular to said first planar
portion longer than that of said first battery, and said battery chamber
comprising:
a first receiving portion for receiving said first battery, said first
receiving portion including a second planar portion confronting said first
planar portion;
a contact plate provided at said second planar portion for providing
battery power, said contact plate including positive and negative
terminals which selectively come into contact with said positive and
negative electrodes of said first battery; and
a second receiving portion, formed as a recess at an opposite planar
portion of said second planar portion of said first receiving portion, for
receiving said second battery in cooperation with said first receiving
portion, said second receiving portion having a cross-sectional area equal
to that of said second battery and a depth equal to the difference between
the lengths of said first and second batteries.
20. The battery chamber according to claim 19 further comprising a
projection means movable between a projecting position where it projects
into said second receiving portion and a retracted position where it is
retracted from said second receiving portion, and a means for urging said
projection means towards said projecting position.
21. The battery chamber according to claim 20, wherein said first and
second batteries generate a respective output voltage which is different
from each other, and said instrument further comprising an electronic
circuit operative at a given supply voltage, and a voltage converting
means connected between said terminals of said contact plate and said
electronic circuit for converting the output voltage of the battery to
said given supply voltage in response to the movement of said projection
means.
22. The battery chamber according to claim 19, wherein said contact plate
includes a lid for said battery chamber movable between first and second
positions for respectively closing and opening the opening of said battery
chamber, and a switch connected between said terminals of said lid and the
circuit of said electronic instrument and provided to move in response to
the movement of said lid, said switch being closed when said lid is at
said first position and being open when said lid is at said second
position. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a portable electronic instrument such as a
camera which is supplied with electric power from a battery and
selectively receives different kinds of batteries, and more particularly
pertains to such an electronic instrument which selectively recieves two
kinds of batteries which are different from each other in their respective
shape and/or output voltage.
2. Description of the Prior Art
Several kinds of dry batteries, which are different in shape or in their
output characteristics e.g. the open output voltage, the current-carrying
capacity or the leakage current, are available in the market for use in
portable electronic instruments. For example, batteries for use in cameras
include a cylindrical battery cell of the AA type with an open output
voltage of 1.5 V, a button shape battery cell of the S-76 type with an
open output voltage of 1.5 V, and a packaged battery cell having a package
different from the AA and S-76 type batteries in shape and output
characteristics. It has been a common practice that a battery which is the
most favorable battery for an electronic instrument is determined and
selected, upon designing of the instrument from the commercially available
batteries in consideration of the operating conditions of the instrument
such as the load current of the instrument, the whole weight of the
instrument and the life of the battery. Hence, battery chambers of
electronic instruments have been designed to accommodate only the selected
kind of particular batteries. In other words, other kinds of batteries
with a different shape cannot be used.
However, the battery to be used in an instrument may not necessarily be
limited to a single kind but the instrument may be designed to selectively
receive plural kinds of batteries. Especially, in the case where the
particualar kind of battery that is most suitable for the instrument, is
expensive and can not be easily obtained in ordinary stores, it will be
convenient for the user if the instrument can be used with a conventional
battery as a secondary battery which is inexpensive and available in the
ordinary stores even if the secondary battery is inferior to the
particular battery in efficiency and other properties. Such selective
accommodation of different kinds of batteries will enable the user to
choose the kind of battery according to a given set of circumstances.
Meanwhile, it sometimes happens that different kinds of batteries are
different from each other in their shape and output voltage. However,
compactness is a requisite characteristic for the design of a portable
electronic instrument such as a camera and the battery chamber of the
instrument should be as compact as possible even when batteries of
different shapes are to be received in the chamber. Additionally, the
components and circuit constants of the circuit of the instrument are
generally determined such that the circuit operates in its best condition
when it is supplied with electric power from the particular kind of
battery. If the secondary battery has a different output voltage from that
of the particular battery, the circuit must be designed to adapt for the
different output voltages. Otherwise, the circuit operates badly or might
be damaged. For example, if the output voltage of the secondary battery is
higher than that of the particular battery, the circuit designed to
operate with the output voltage of the particular battery may be destroyed
by the higher supply voltage. If the output voltage of the secondary
battery is lower than that of the particular battery, the circuit may
operate badly or may be inoperative due to the lower voltage supply.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide an electronic
instrument which selectively receives two kinds of batteries that are
different from each other in shape and output voltage.
Another object of the present invention is to provide an electronic
instrument which operates in the best condition with the voltage supplied
from either one of the batteries which have a difference in their output
voltages.
Yet another object of the present invention is to provide an electronic
instrument in which the different output voltages of different kinds of
batteries are effectively used.
A further object of the present invention is to provide a battery chamber
for an electronic instrument which is compact in size and receives two
kinds of batteries of different shapes.
Still a further object of the present invention is to provide a battery
chamber for an electronic instrument that detects the kinds of battery
loaded therein.
An additional object of the present invention is to provide a battery
chamber for an electronic instrument which selectively holds different
kinds of batteries of different shapes such that the bateries will not
jolt therein.
According to the present invention, a battery chamber for an electronic
instrument is constructed to commonly receive two kinds of batteries of
different shapes such that a part of each battery is received in the same
space of the battery chamber. Accordingly, the battery chamber is compact
in size. Additionally, a member projecting into the battery chamber
determines which kind of battery is received in the battery chamber. In
accordance with that determination, the output voltage of the battery
loaded in the battery chamber is converted to a voltage at which the
circuit of the electronic instrument operates in its best condition, such
that the circuit operates in the best condition with the voltage supplied
from either one of the batteries which have different shapes and output
voltages.
DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of a camera as an example of an electronic
instrument;
FIGS. 2A and 2B are respective is a perspective views of two kinds of
exemplary batteries which are to be received in an electronic instrument
of the present invention;
FIG. 3 is a partially sectional view of a battery chamber according to an
embodiment of the present invention which selectively receives the two
kinds of batteries shown in FIGS. 2A and 2B;
FIG. 4 is a horizontal sectional view of the battery chamber shown in FIG.
3;
FIGS. 5A and 5C are cross-sectional views of the left-hand portion of the
battery chamber shown in FIG. 3 showing the operating relationship of the
battery determination member and associated switch members, and FIGS. 5B
and 5D are cross-sectional views of the right-hand portion of the battery
chamber shown in FIG. 3 showing the operating relationship of the battery
determination member and associated switch members;
FIG. 6 is a schematic block diagram of one form of electronic circuit of
the electronic instrument of the present invention;
FIG. 7 is a perspective view of another kind of battery;
FIG. 8 is a horizontal sectional view of the battery shown in FIG. 7;
FIG. 9 and FIG. 10 are respective longitudinal sectional views of a battery
chamber which receive the battery shown in FIG. 7;
FIG. 11 and FIG. 12 are respective horizontal sectional views of the
battery chamber respectively taken on line J--J and K--K in FIG. 10;
FIG. 13 is a perspective view of the lid shown in FIG. 9;
FIG. 14 is a longitudinal sectional view of the lid taken on line L--L in
FIG. 13;
FIG. 15 is a perspective view showing a battery determining means for the
battery shown in FIG. 7;
FIG. 16 is a perspective view of a battery similar to FIG. 7;
FIG. 17 is a longitudinal sectional view of the battery taken on line N--N
in FIG. 16;
FIG. 18 is a perspective view of still another kind of battery;
FIG. 19 is a perspective view showing a battery determining means for the
battery shown in FIG. 18; and
FIG. 20 is a schematic block diagram of another form of electronic circuit
of the electronic instrument of the present invention.
The above and other objects and features of the invention will be apparent
from the following description of the disclosure found in the accompanying
drawings and the novelty thereof set forth in the appended claims.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The following explanation is directed to an embodiment wherein the battery
chamber of an electronic instrument according to the present invention is
adapted for a photographic camera.
With reference to FIG. 1, camera 2 includes electronic flash device 4. An
automatic exposure control device, an automatic focusing device, a film
wind-up and rewinding device, a voice indication producing or voice
generating device and a data recording or imprinting device are included
in the camera but not shown in FIG. 1. Battery chamber 6 is provided on
one side of camera 2. Battery chamber 6 is adapted to selectively
accommodate two kinds of batteries which are different from each other in
their output voltage and shape. As one of such two kinds of batteries,
battery chamber 6 may receive a pair of manganese or alkaline-manganese
battery cells of the AA type with an open output voltage of 1.5 V. The
battery cells may be loaded one-by-one and supported independently of each
other. Other kinds of batteries may be included in a package of battery
cells which package is different from the AA type battery in shape and
which produces an open output voltage of e.g., for example, 6.0 V. These
batteries and battery package may be loaded in the battery chamber with a
lid at the bottom of the chamber being opened. The batteries thus loaded
supply electric power to various devices and circuits in the camera.
The following explanation concerns an embodiment of the battery chamber
according to the present invention, with reference to FIGS. 2A, 2B through
5A, 5B, 5C and 5D. Battery package 10 shown in FIG. 2A of a first of
battery includes a pair of lithium battery cells with open output voltage
of e.g. 3.0 V. The battery cells are arranged side-by-side with their
electrodes being disposed oppositely and are covered by an insulating
outer wall of a synthetic resin material such that the battery cells are
packaged integrally as a unit. In package 10, the battery cells are
connected in series with each other. Package 10 is provided with positive
electrode 10p and negative electrode 10m in the recess at the bottom 10d.
The lithium battery cell is larger in diameter and shorter in length in
comparison with the well-known AA type cell. As package 10 contains a pair
of aforementioned lithium battery cells arranged side-by-side, it is
larger in its horizontal cross-sectional area and shorter in height as
viewed in the drawing, in comparison with the side-by-side arrangement of
a pair of AA type battery cells. One side 10a of battery package 10 is
formed substantially flat while the other side 10b is formed with vertical
groove 10c so that package 10 has the shape of two integrally coupled
semi-cylinders. The second type of battery is composed of well-known AA
type cells 8a and 8b shown in FIG. 2B.
FIG. 3 shows the structure of a battery chamber which selectively receives
a single battery package 10 and a pair of AA type batteries 8 as shown in
FIG. 2A. It should be noted that FIG. 3 is a partially sectional view of
battery chamber 6 as viewed from the bottom of camera 2, i.e., in the
direction in which the batteries are inserted.
Battery chamber 6 is composed of lid 11, first receiving portion 7 formed
at the rear of opening 6a through which battery cells are put into and out
of the chamber, and second receiving portion 9 formed at the rear of first
receiving portion 7. First receiving portion is formed with side wall 7a
and upper wall 7b for cooperatively enclosing and supporting battery
package 10. Side wall 7a is formed, as shown in cross-section in FIG. 4,
with a substantially flat plane at one side and with projection 7c which
extends vertically. Projection 7c is adapted to engage into groove 10c of
battery package 10 as shown in the horizontal cross sectional view of FIG.
4. If battery package 10 is erroneously attempted to be loaded in battery
chamber 6 with the electrodes of the package being inverted from the
positions shown in FIG. 2a, projection 7c engages flat side 10a of battery
package 10 and prevents it from being mistakingly inserted. Second
receiving portion 9 is formed with side wall 9a and upper wall 9 b for
receiving and holding the front ends of AA type batteries 8a and 8b,
i.e., the portions of the batteries longer than battery package 10. The
relative position of the first and second receiving portions is determined
such that electrodes 8m and 8p of AA type batteries 8a and 8b are located
substantially at the same positions as those of electrodes 10m and 10p of
battery package 10. On upper wall 9a of second receiving portion 9,
connecting piece 14 is provided for serially connecting two AA type
batteries 8a and 8b at the electrodes opposite from electrodes 8p and 8m.
Detecting pins 13 and 15 are provided on side wall 9a of second receiving
portion 9 for detecting the loading of an AA type battery. Detecting pins
13 and 15 are connected with movable contacts S7a and S6a (FIGS. 5A, 5C
and 5B, 5D, respectively) of switches S7 and S6 (FIG. 6) at one of their
respective ends such that their other ends are urged to project into the
interior of second receiving portion 9. The other ends of detecting pins
13 and 15 are formed with slanted plane 13a and 15a which engage the top
of the cylindrical portion of the AA type batteries when the batteries are
inserted into second receiving portion 9 such that detecting pins 13 and
15 are pushed back to change over switches S6 and S7 as will be described
in detail later with respect to FIGS. 5A-5D. At the same time, the spring
force of the movable contacts presses the AA type batteries against the
opposite side wall of second receiving portion 9 to prevent jolting of the
batteries within the battery chamber.
Lid 11 is adapted to cover opening 6a of battery chamber 6 is and hinged to
camera 2 to turn between open and closed positions. Projection 12 is
formed on the edge of lid 11 for restraining lid 11 at its closed
position. Contact springs 16m and 16p are provided on inner wall 11a of
lid 11 and are adapted to be in contact with electrodes 10m and 10p of
battery package 10 and electrodes 8m and 8p of AA type batteries 8a and
8b. In other words, contact springs 16m and 16p selectively and commonly
come into contact with both pairs of electrodes 10m and 10p and 8m and 8p.
Contact spring 16p is directly connected with positive power source
terminal 18 of the camera circuit shown in FIG. 6 (a terminal of the
camera circuit to be connected with positive electrode of the battery
power source) through lead wire 17a arranged in the vicinity of hinge 11b
for lid 11. Contact spring 16m is connected with contact 17b which is
provided on the inner wall of lid 11. Negative power source terminal 19 of
the camera circuit (the terminal of the camera circuit to be connected
with the negative electrode of the power source battery) is provided on
the bottom wall of the battery receptacle body, at the position opposite
to contact 17b.
With this structure, contact 17b is brought into contact with the negative
power source terminal 19 of the camera circuit only when lid 11 is closed.
Terminal 19 and contact 17b compose a switch mechanism which electrically
disconnects the camera circuit from the batteries with lid 11 being open
and connects the camera circuit with the batteries with lid 11 being
closed. This structure protects the camera circuit from the breakage due
to misoperation of the camera operator as follows. That is, as the
contacts for the batteries are provided on the inner wall of lid 11, it is
possible that electrodes 10m and 10p of battery package 10 are brought
into contact, and electrically connected, with contact springs 16m and 16p
with lid 11 being at the open position and battery package being outside
of the battery chamber. In this case aforementioned projection 7c
projecting into battery chamber 6 for preventing the package from being
loaded improperly, does not operate and the electrodes of the battery
package can be easily connected oppositely with contact springs. Thus, if
the camera circuit is directly connected with the batteries not through
the above mentioned switch mechanism, it is likely to occur that the
camera circuit will be damaged by the power supply of the opposite
polarity. In view of this, the switch mechanism is provided for
disconnecting the camera circuit from the batteries and to protect the
camera circuit from damage due to such misoperation while lid 11 is open.
Another countermeasure is possible for the protection of the camera circuit
from damage. Between the contacts on lid 11 and the power source terminals
of the circuit of the electrically operated instrument, e.g., a camera, a
normally open switch may be provided which has a movable contact adapted
to move in response to the opening and closing of lid 11 in such a manner
that the switch is closed with the lid being closed, and opened with the
lid being open. This operation can be attained by an insulating member
which is provided on the movable contact of the normally open switch and
which is arranged to project in the path of lid 11.
As shown in FIGS. 5A-5D, switch 6 has movable contact S6a and fixed contact
S6b, and switch S7 has movable contact S7a and fixed contacts S7b and S7c
arranged on both sides of movable contacts S7a. Movable contacts S6a and
S7a are biased to the right such that switch S6 is normally open, and
change-over switch S7 is normally connected with fixed contact S7c as
shown in FIGS. 5(A) and 5(B), respectively. This condition is accomplished
when battery package 10 is loaded in first receiving portion 7 to supply a
high voltage of 6 V across the power source terminals of the camera. When
AA type batteries are loaded in second receiving portion 9, detecting pins
13 and 15 are pushed away to the left to close switch S6 and connect
switch S7 with contact S7b as shown in FIGS. 5(C) and 5(D), respectively.
With this condition, a low voltage of 3 V is supplied across the power
source terminals of the camera.
FIG. 6 shows an exemplary camera circuit which is supplied with power from
the two kinds of batteries described, supra. In this Figure, battery
package 10 generates an output of 6 V while AA type batteries 8 generate
an output of 3 V. It should be noted that although the Figure shows as if
both kinds of batteries are loaded in the camera, only one of them is
actually loaded. When AA type batteries 8 are loaded, switch S6 is closed
as described earlier so that the output of AA type batteries 8 is directly
applied to the circuit on the left side in the Figure. Thus, switch S7 is
connected to contact S7b so that voltage booster circuit E for electronic
flash circuit F operates at the lower power source voltage. When battery
package 10 is loaded instead of AA type batteries 8, switch S6 will open
as described before so that the output voltage of battery package 10 is
reduced by voltage reducing circuit G and applied to the various circuits
on the left side of the Figure. Thus, switch S7 has been changed over to
contact S7c so that voltage booster circuit E operates at the higher power
source voltage.
As described earlier, camera 2 includes automatic exposure control and
focusing circuit B, DC-DC converter or voltage booster circuit E,
electronic flash circuit F, film wind-up and rewinding circuit A, voice
generator or voice indication producing circuit C, data recording or data
imprinting circuit D and voltage reducing circuit G for reducing the
output voltage of the battery package. Voltage booster circuit E includes
primary coils L1 and L2 and secondary coil L3. Primary coils L1 and L2 are
wound in the same direction and serially connected with each other. Fixed
contact S7b of switch S7 is connected between primary coils L1 and L2,
while fixed contact S7c is connected with the free end terminal of primary
coil L1. Accordingly, when battery package 10 is loaded in battery chamber
6 with switch S7 being connected to contact S7b, electric power is
supplied through coils L1 and L2 such that the output voltage of battery
package 10 is raised to about N3/(N1+N2) times the original voltage. When
AA type batteries 8 are loaded with switch S7 being connected to contact
S7c, the electric power is supplied through coil L2 and the output voltage
of the batteries is raised to about N3/N2 times the original voltage. The
characters N1, N2 and N3 represent the numbers of turns of coils L1, L2
and L3, respectively. Switch S5 is manually closed for flash photography
to actuate voltage booster circuit E. Transistor Q4 for the control of the
voltage boosting or raising operation is rendered conductive to stop the
operation of voltage booster circuit E when voltage reducing circuit G
operates and circuits A, B, C and D are supplied with electric current.
Electronic flash circuit F is supplied with electric power from secondary
coil L3 of voltage booster circuit E and effects flash light emission with
the charge of a main capacitor not shown in the Figure.
Wind-up and rewinding circuit A includes switch S2 for the selection of the
wind-up and rewinding operation, wind-up control switch S3 which is closed
in response to termination of exposure and opened upon completion of film
wind-up, and film detecting switch S4 which is located in a predetermined
position along the path of the film within the camera body, for example,
in the vicinity of the camera sprocket wheel such that switch S4 is closed
with a film located at that position and is open with no film positioned
there. Transistors T1 and T2 are connected with those switches such that
transistor T1 conducts in response to the change-over of switch S2 to the
wind-up operation side and closure of switch S3 and such that transistor
T2 conducts in response to the change-over of switch S2 to the rewinding
operation side and closure of switch S4. With this circuit arrangement,
wind-up and rewinding driving circuit A drives motor M in a normal
direction with transistor T1 being conductive and in the reverse direction
with transistor T2 being conductive. A wind-up and rewinding mechanism
(not shown) in camera 2 performs a wind-up operation with motor M driven
in the normal direction and a rewinding operation with motor M driven in
the reverse direction.
Automatic exposure control and focusing circuit B includes switch S1 which
is closed in response to depression of shutter release button 5 (see FIG.
1), and transistors T3 and T4 which conduct in response to the closure of
switch S1. Circuit B performs an automatic exposure control and focusing
operation with transistor T4 being conductive. In the case where the
brightness of an object to be photographed is lower than a predetermined
level, circuit B supplies a flash firing signal to electronic flash
circuit F and fires the latter when the diaphragm aperture reaches a value
commensurate with an automatically detected camera-to-object distance.
Transistor T5 is conductive with wind-up and rewinding circuit A being in
the wind-up state and transistor T6 is conductive with circuit A being in
the rewinding state to prevent the conductive of transistor T3 and prevent
the operation of circuit B. When switch S1 is closed to actuate circuit B,
transistor T7 conducts to prevent conduction of transistors T1 and T2 and
prevent the wind-up and rewinding operation of motor M. Voice indication
producing circuit C receives signals from automatic exposure control and
focusing circuit B, wind-up and rewinding driving circuit A and produces
through speaker SP voice indications such as "load film", "change the
camera-to-object distance," and so on.
Data recording or data imprinting circuit D includes an LCD (liquid crystal
display) device for displaying date and time data supplied from an
electronic clock device (not shown), battery cell DB for driving such
devices, lamp L for the exposure of imprinted data, and imprinting
initiation switch S8 which is closed, just before the film exposure, in
response to operation of a camera mechanism, e.g., an automatic focusing
device, to energize lamp L.
Voltage reducing circuit G is adapted to lower the high voltage from
battery package 10 and includes zener diode ZD, diode D1 and transistor Q6
for short-circuiting diode D1. When transistor Q6 is blocked, the output
voltage of battery package 10 is reduced by voltage reducing circuit G to
a first reduced voltage, e.g., 4.0 V which is determined by zener diode ZD
and diode D1. When transistor Q6 is conductive, diode D is short-circuited
thereby and the output voltage of battery package 10 is reduced to a
second reduced voltage, e.g., 3.0 V which is determined by zener diode
Z.D. Both first and second reduced voltages are output from the emitter of
transistor Q3. In this way, reduced voltage generating circuit G is
arranged to generate two different voltage levels so that automatic
exposure control and focusing circuit B, voice generating circuit C and
data imprinting circuit D are driven by the second reduced voltage which
is approximately equal to the output voltage of AA type batteries, while
wind-up and rewinding circuit A is driven by the first reduced voltage
which is higher than the second.
Voltage reducing control circuit H is provided with five transistors having
collectors and emitters parallelly connected with one another and the
collectors connected through resistor to voltage reducing circuit G, i.e.,
the node between the collector of transistor Q1 and the base of transistor
Q2. The bases of the five transistors are respectively connected to
switches S1, S3 and S4, voice generating circuit C and data imprinting
circuit D. Accordingly, when any one of circuits A, B, C and D is in
operation, a corresponding transistor in voltage reducing control circuit
H becomes conductive to actuate voltage reducing circuit G.
Reducing voltage control circuit I controls voltage reducing circuit G and
determines which one of two levels of reduced voltages is to be generated
from voltage reducing circuit G. Reduced voltage control circuit I
includes three transistors having their collectors and emitters connected
in parallel with each other, with the collectors connected to the base of
transistor Q5. The bases of those three transistors are respectively
connected to switch S1, voice generating circuit C and data imprinting
circuit D. Accordingly, when any of the circuits B, C and D is in
operation, the corresponding transistor is rendered conductive to render
transistors Q5 and Q6 conductive and short-circuit diode D1, thereby
reducing the voltage to the second reduced voltage. However, when wind-up
and rewinding circuit A is in operation, the above mentioned three
transistors are all blocked to block transistors Q5 and Q6 so that the
voltage is reduced to the first reduced voltage which is higher than the
second reduced voltage by an amount commensurate with the forward voltage
across diode D1.
Finally, the operation of camera 2 will be explained. When shutter release
bottom 5 is depressed with switch S2 being connected to the film wind-up
operation side and switch S3 being open, switch S1 is closed at the
initial stage of the shutter release depression to effect object
brightness measurement and camera-to-object distance measurement or focus
detection. After the camera objective lens is moved to an in-focus
position commensurate with the detected object distance, film exposure is
effected with a shutter speed and a diaphragm aperture (or the amount of
maximum shutter opening in the case of a diaphragm-shutter mechanism). In
case the object brightness is lower than a given level, upon arrival of
the diaphragm-shutter aperture at a value commensurate with the detected
object distance, circuit B supplies a flash firing signal to electronic
flash circuit F to effect flash light emission. When a cycle of
photography is completed, switch S3 is closed to effect film wind-up and
shutter cocking by circuit A. When the shutter has been cocked and the
film has been wound-up for one-frame length, switch S3 opens and the
wind-up operation is stopped. When all the frames of the have been
exposed, the film strain on the film disables further wind-up of the film
and change-over switch S2 to the rewinding operation side. It is to be
noted that switch S2 is maintained at the rewinding side by a mechanism
(not shown) until rewinding operation is completed. With the change-over
of switch S2, motor M in circuit A is driven in the reverse direction and
rewinding of the film is effected. When the film has been withdrawn to
such an extent that the film does not exist at a certain position along
its path, switch S4 opens to stop motor M.
In the above embodiment, the first battery is composed of two lithium
battery cells arranged side-by-side in a package with positive and
negative electrodes being located on the same side of the package, and the
second battery is composed of two AA type manganese or alkaline-manganese
battery cells arranged side-by-side with their electrodes, which are not
in contact with the contact terminals 16p and 16m, connected with each
other through connecting piece 14. The AA type batteries may also be
arranged in a package with their electrodes being connected within the
package.
Further, in the embodiment just described, the first and second batteries
output a different voltage, but batteries having the same output voltages
may also be employed.
Next, the second embodiment of the invention will be explained with
reference to FIGS. 7 through 15. In this embodiment, the battery package
has a similar outer shape to that of two AA type batteries arranged
side-by-side as will be described later. With reference to FIG. 7, battery
package 20 has a similar construction to that of battery package 10 shown
in FIG. 2(A) and includes two lithium battery cells which have
respectively an open voltage of 3 V. The battery cells are arranged
side-by-side with their electrodes being reversed and covered by an
insulating synthetic resin material, thereby being packaged as a unit.
Those battery cells are electrically connected in series with each other
and positive electrode 20p and negative electrode 20m are exposed on the
top plane of battery package 20. The lithium battery cell has a shape that
is equal in diameter to and shorter in length than a conventional AA type
battery. On the top plane of battery package 20, projection 20a is
provided between positive electrode 20p and negative electrode 20m for
identifying the battery package from another type of battery.
As seen in FIG. 8 which shows a cross section of battery package 20 as cut
horizontally as vewed in FIG. 7, battery package 20 has a height as viewed
in FIG. 8 that is a little longer than the diameter of the AA type
battery. The width of the package is approximately equal to double that of
the diameter of the AA type battery. The battery chamber of the camera
body has an internal size that substantially fits battery package 20.
Accordingly, when a pair of AA type batteries are loaded side-by-side in
the chamber, the batteries will jolt therein. To cope with this, the
battery chamber is formed at appropriate positions on its inner wall, with
projections which engage and support AA type batteries to prevent the
jolting of the batteries. Battery package 20 is formed with recesses at
positions where the recesses are brought into alignment with the
projections when a battery package has been loaded. In this way, the
projections do not interfere with the insertion of the battery package.
With reference to FIG. 7, battery package 20 is formed with recesses 20b,
20c, 20d, 20e, 20f and 20g for that purpose.
FIGS. 9 through 12 show the battery chamber of camera 2, FIGS. 9 and 10 are
vertical sectional views of battery chamber 21, respectively, in the case
where it contains battery package 20 and in the case it contains AA type
batteries. FIGS. 11 and 12 are horizontal sectional views of battery
chamber 21 respectively taken along lines J--J and K--K in FIG. 10. With
reference to FIG. 11, on the upper portion of inner wall of battery
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