JPWO1997003473A1 - Battery pack storage device and battery pack - Google Patents

Abstract

(57) [Abstract] A battery storage device for use in a battery-powered electrical or electronic device includes multiple positive and negative terminals, and is characterized by having a first mounting state in which the battery is connected to one set of positive and negative terminals, a second mounting state in which the battery is connected to another set of positive and negative terminals, a third mounting state that combines the first and second mounting states, and a fourth mounting state in which the battery is connected to all positive and negative terminals. This battery storage device allows the battery pack to be replaced without interrupting the power supply to the electrical or electronic device. This eliminates the need for an auxiliary power source such as a sub-battery in the electrical or electronic device itself, allowing for a unified power system including a DC/DC converter and charging circuit. This simplifies the electrical circuitry within the system, saving space inside the housing and reducing costs.

Description

[Detailed Description of the Invention] Battery Pack Storage Device and Battery Pack [Technical Field] The present invention relates to a battery storage device and battery pack used in battery-powered electrical and electronic devices, such as portable computers. In particular, the present invention relates to a battery storage device and battery pack that allows efficient battery pack replacement. More specifically, the present invention relates to a battery storage device and battery pack that allows battery pack replacement without interrupting the power supply to the electrical and electronic devices even for a moment.

[Background Art] Recent technological advances have led to the widespread adoption of small, lightweight electrical and electronic devices designed and manufactured for portable outdoor use. The so-called "notebook computer" (hereafter simply referred to as "PC" or "system") is a good example of this.

Figure 20 shows the external structure of a notebook computer (hereinafter simply referred to as a "PC" or "system") 100. This figure is substantially identical to the electronic computer disclosed in Patent Application No. 06-30003 (Serial Number: JA9-94-621), which is assigned to the present applicant. The illustrated PC 100 is a so-called "lidded structure" consisting of a thin main body 110 and a lid 120 that can be opened and closed relative to the main body 110.

The lid 120 includes a shallow upper casing 121. A pair of generally cylindrical projections 122 are integrally formed on the lower edge of the upper casing 121, and the pair of projections 122 are rotatably supported on the main body 110, thereby hingedly connecting the lid 120 to the main body 110. A liquid crystal display (LCD) 123 serving as a display means for the PC 100 is embedded in the approximate center of the open side of the upper casing 121 (i.e., the rear side of the lid 120). The lid 120 is opened and closed relative to the main body 110 by sliding opening/closing operation members 124, located approximately in the front portion of each of the left and right sides of the upper casing 121, in the forward and backward directions.

The main body 110, on the other hand, includes a shallow lower casing 111. A support plate 112 of a predetermined size is installed within the lower casing 111 to conceal the rear portion of the upper opening. A keyboard/TrackPoint 113 ("TrackPoint" is a trademark of IBM Corporation) is located approximately in the center of the upper opening as an input means for the PC 100. A pair of speakers 114 for audio output are embedded in both left and right corners in front of the keyboard 113. A pair of approximately cylindrical tongues 115 are integrally formed on the rear edge of the keyboard 113. These tongues 115 are pivotally supported on the front edge of the support plate 112, thereby hingedly connecting the keyboard 113 to the support plate 112 so that the keyboard 113 can be opened and closed. Additionally, an indicator unit 115A is provided on the upper surface of the hinge at the rear end of the lower housing 111 for displaying the status of the system 100, such as the remaining battery capacity, the usage status of the PC card, the usage status of the floppy disk drive (FDD), the usage status of the hard disk drive (HDD), and whether the power is on.

Figure 21 shows the PC 100 with the lid 120 and keyboard 113 open, exposing the internal structure of the main body 100. Within the lower casing 111, a partition 116 is formed by bending a thin metal plate into a predetermined shape to separate the front and rear compartments. The rear compartment, concealed by the support plate 112 and partition 116, houses a system board (not shown) with major electrical components mounted on its surface, such as a central processing unit (CPU), system memory, a memory controller, ROM, a video controller, and an audio controller. Because the rear compartment is relatively narrow, the electrical components within the compartment are densely packed. Additionally, input/output devices such as HDD pack 117 and CD-ROM drive 118, as well as battery pack 119, which serves as the main power source, are removably mounted in the front chamber in front of bulkhead 116. The front side of bulkhead 116 is provided with corresponding connectors (not shown) for mechanically and electrically connecting to the terminals of HDD pack 117, CD-ROM drive 118, and battery pack 119.

One characteristic of such portable personal computers is that the surface area of the housing (lower casing 111) is very small, limiting the number of openings and connectors available for attaching, detaching, or replacing various devices. For example, as shown in Figure 20, the front side of main body 110 is provided with a drawer for replacing CDs (the storage medium). Furthermore, the right side of main body 110 is provided with a battery slot 132 for inserting and removing battery pack 119. Further back, there is a PC card slot 134 for inserting PC cards (two Type I/II cards or one Type III card) and an input port for an external keyboard/mouse (not shown). Additionally, as shown in Figure 22, the rear side of the main body 110 is equipped with a jack 135 for connecting an external power supply (AC adapter), and a serial port, parallel port, CRT port, SCSI port, and other ports are located inside the protective rear door. Also, as shown in Figure 22, the left side of the main body 110 is equipped with a connector 137 for connecting expansion devices that are pin-compatible with the ISA bus (an ISA bus is one of the input/output buses within the PC 100; ISA stands for "Industry Standard Architecture"), as well as a power switch 138. In short, various devices compete for the narrow surface area of the PC 100. Furthermore, adding more openings and connectors would likely result in a deterioration of the mechanical strength of the case.

Another feature of these portable personal computers is that they can be powered by a built-in battery, allowing them to be used in places where commercial power is unavailable. The built-in battery, in fact, takes the form of a "battery pack" (e.g., battery pack 119 in Figure 21) in which multiple battery cells are connected in series or parallel to provide sufficient power for the system. Each battery cell is rechargeable, using a material such as NiCd, NiMH, or Li-Ion, for reusability.

It's easy to imagine that while commercial power sources are virtually inexhaustible, battery packs have a finite capacity. For example, the battery packs used in notebook computers typically last only a few hours on a single charge, although this varies depending on the model and operating conditions. Therefore, it's not uncommon for a battery pack to run out of power while you're using your PC, requiring you to replace it with a new (or fully charged) one.

Incidentally, many of the storage devices within a PC are volatile, such as system memory (DRAM) and video RAM. Therefore, if the power to the PC is interrupted even temporarily while in use, the data being worked on and files created in these volatile storage devices are lost and cannot be recovered. As a result, the user must start over from the beginning.

Naturally, this type of data loss problem can also occur when replacing the battery pack. To address this issue, many battery-powered electrical and electronic devices are equipped with a relatively small auxiliary battery (also known as a "sub-battery") to provide backup power for the short period required to replace the main battery. Portable electrical and electronic devices equipped with an auxiliary power source equivalent to a sub-battery are described, for example, in Japanese Utility Model Publication Nos. 63-27357, 07-4662, and JP Patent Publication No. 05-130749.

FIG. 23 shows a schematic configuration (conventional example) of the power system of a notebook computer 100 that also uses a sub-battery.

In the figure, reference numeral 201 denotes an AC adapter for converting input voltage from a commercial power source (typically 100V AC) to DC voltage. Reference numeral 202 denotes a battery pack used within PC 100, which consists of multiple battery cells and supports approximately two to three hours of operation on a single full charge. Block 203 denotes a circuit for selectively connecting power supplied from AC adapter 201 and battery pack (hereinafter also referred to as the "main battery") 202 and charging main battery 202 with power supplied from AC adapter 201. When both AC adapter 201 and main battery 202 are installed, block 203 prioritizes power supplied from AC adapter 201. Reference numeral 204 denotes a main DC/DC converter for stepping down the DC voltage input from AC adapter 201 or main battery 202 to a voltage level usable by system 100. Reference numeral 206 denotes the sub-battery. Sub-battery 206 literally supplements main battery 202 and is used to back up volatile memory within system 100 for a short period of time, such as while the main battery 202 is being replaced. Due to space-saving and low-cost requirements, sub-battery 206 is a small power supply consisting of, for example, three NiCd or NiMH rechargeable coin batteries. Its capacity is only about three minutes of system 100 power during low-power operation (such as suspend mode). Block 207 is a circuit that manages the charging operation of sub-battery 206. Block 208 is a circuit that selectively charges and discharges sub-battery 206. Reference numeral 209 is a sub-DC/DC converter that adjusts the discharge voltage of sub-battery 206 to a voltage level usable by system 100 during discharge. Block 205 is a circuit for selectively supplying the output voltage of either the main DC/DC converter 204 or the sub DC/DC converter 209 to a system load 211. The system load 211 refers to the electrical circuits in the system 100 that actually consume power, such as the CPU, system memory, HDD, and CD-ROM drive. The power management processor 210 is a dedicated processor for controlling the flow of power from each power supply 201, 202, and 206. It monitors the operating status of the system load 211 and outputs control signals to blocks 203, 204, 207, 208, and 209. The main control operations of the power management processor 210 are: (1) prioritizing power supply from the AC adapter 201 over the main battery 202; (2) switching between charging and discharging the main battery 202 and the sub-battery 206; (3) charging the main battery 202 and the sub-battery 206; and (4) using power supply from the main DC/DC converter 204 during normal operation and switching to power supply from the sub-DC/DC converter 209 only when the main battery 202 is replaced.

As shown in Figure 23, a power system including a sub-battery has already been adopted, for example, in the ThinkPad series sold by IBM Japan ("ThinkPad" is a trademark of IBM Corporation).

As mentioned above, the auxiliary battery is designed to replace the main battery when power is lost. However, when electrical and electronic equipment is equipped with an auxiliary battery in addition to the main battery, the following problems arise:

(1) In addition to the primary power source (AC adapter 201 and main battery 202), the computer will have other power systems. Naturally, this requires additional circuitry for the sub-battery 206. The blocks enclosed by dashed lines in Figure 23 are additional components required for the addition of the sub-battery 206. These represent a significant design and manufacturing burden for notebook PCs, which are subject to strict constraints such as space saving, light weight, and low cost. Furthermore, the power management processor 210 must also drive and control these additional blocks, increasing the complexity of its programming.

(2) The capacity of the sub-battery 206 is extremely small. Therefore, for example, in the ThinkPad series mentioned above, power is supplied from the sub-battery 206 only when the computer is in low-power operation (suspend) mode. When replacing the main battery 202, the operator manually or automatically switches the system 100 to low-power operation (suspend) mode, thereby receiving backup power from the sub-battery 206. However, if the operator neglects to switch to suspend mode or unexpectedly takes too long to replace the main battery 202, causing the sub-battery 206 to run out of power, data loss can still occur. This risk of data loss is likely unavoidable as long as the combined main/sub-battery system is used.

For this reason, several battery replacement methods have been proposed that do not require a sub-battery and do not cause a power interruption. For example, Japanese Patent Application Laid-Open Nos. 61-135050, 61-250965, 02-61959, 04-286860, Japanese Utility Model Application Laid-Open Nos. 59-141652, 59-146861, and Japanese Utility Model Application Laid-Open No. 04-19715 disclose devices and methods for replacing batteries in an uninterruptible power supply.

Most of the devices/methods disclosed in these publications use a sliding mechanism, where a new battery is inserted into one end of the battery compartment and the old battery is ejected from the other end. Since the positive and negative terminals of the old and new batteries slide over the common terminal of the electrical/electronic device before the exchange is complete, power supply is not interrupted.

However, this sliding mechanism requires an opening on the surface of the PC's case for the new and used batteries. While this may be feasible for devices with ample space, in the case of a notebook PC, as mentioned above, other devices compete for openings on the surface of the case, making it impractical to provide two openings just for the battery pack. Furthermore, drilling a new opening would weaken the mechanical strength of the case. Furthermore, space is required for the new and used battery packs to pass through, but in a case crowded with devices, as shown in Figure 21, it is not permissible to allocate more space than the battery pack's footprint.

Furthermore, because the old battery, with its low terminal voltage, and the new battery, with its high terminal voltage, slide over the common contact, there is a natural risk of a short circuit, in which a large current flows from the new battery to the old battery, damaging both batteries. However, the publication cited above does not address or resolve the issue of short circuits between batteries.

[DISCLOSURE OF THE INVENTION] The object of the present invention is to provide an improved battery storage device and battery pack for use in battery-powered electrical and electronic devices, including portable computers.

It is a further object of the present invention to provide a battery storage device and battery pack that allows for efficient battery pack replacement.

It is a further object of the present invention to provide a battery storage device and battery pack which allows the battery pack to be replaced without momentarily interrupting the power supply to the electrical and electronic equipment.

It is a further object of the present invention to provide a battery storage device and a battery pack that allow battery pack replacement without requiring a sub-battery and without interrupting the power supply to electrical and electronic devices.

The present invention has been made in consideration of the above-mentioned problems, and a first aspect thereof is a battery storage device for use in a battery-powered electrical or electronic device, the battery storage device including a plurality of positive terminals and a plurality of negative terminals.

A second aspect of the present invention is a battery storage device for use in a battery-powered electrical or electronic device, which includes multiple positive terminals and multiple negative terminals, and has three mounting states: a first mounting state in which the battery is connected to one set of positive and negative terminals; a second mounting state in which the battery is connected to another set of positive and negative terminals; a third mounting state that combines the first and second mounting states; and a fourth mounting state in which the battery is connected to all of the positive and negative terminals.

It is even more preferable if the battery storage device according to the second aspect further includes a locking mechanism that prohibits removal of the battery in the first mounted state.

The locking mechanism may also permit removal of the battery in the fourth mounting state.

A third aspect of the present invention is a battery storage device for use in a battery-powered electrical or electronic device, the battery storage device having a shallow bottom, a first side wall on which a plurality of positive terminals are disposed, and a second side wall opposing the first side wall on which a plurality of negative terminals are disposed.

A fourth aspect of the present invention is a battery storage device for use in a battery-powered electrical or electronic device, characterized in that the battery storage device has a shallow bottom, a plurality of positive terminals disposed on a first side wall, and a plurality of negative terminals disposed on a second side wall opposite the first side wall, and is capable of connecting to one battery via one set of positive and negative terminals and to another battery via another set of positive and negative terminals.

The battery storage device according to the fourth aspect preferably further includes a locking mechanism that prevents removal of a single battery when only one battery is connected to the storage device via one pair of positive and negative terminals.

The battery may further include a detection means for detecting connection to another battery via another set of positive and negative terminals, and an unlocking means for unlocking the locking mechanism in response to the detection result by the detection means.

A fifth aspect of the present invention is a battery storage device for use in a battery-powered electrical or electronic device, comprising three first electrode terminals connected in parallel and two parallel electrode terminals having polarities opposite to those of the first electrode terminals, with backflow prevention elements inserted into two of the first electrode terminals.

A sixth aspect of the present invention is a battery pack for use in a battery-powered electrical or electronic device, the battery pack including a plurality of positive terminals and a plurality of negative terminals.

A seventh aspect of the present invention is a flat, oblong battery pack for use in a battery-powered electrical or electronic device, having a substantially semi-cylindrical side surface, a first end face including three positive terminals, and a second end face facing the first end face and including two negative terminals.

Thus, with the battery storage device and battery pack according to the present invention, the battery pack can be replaced without interrupting the power supply to the electrical/electronic device.

Furthermore, since auxiliary power sources such as sub-batteries can be completely eliminated, the power system, including the DC/DC converter and charging circuit, can be unified. This simplifies the electrical circuitry within the system, saving space inside the device's housing and reducing costs.

Further objects, features, and advantages of the present invention will become apparent from the following detailed description of the present invention and the accompanying drawings.

[Brief Description of the Drawings] Figure 1 shows the external configuration of a notebook PC 100 according to a first embodiment of the present invention.

FIG. 2 is an enlarged perspective view of the battery receptacle 10. As shown in FIG.

FIG. 3 is an electrical circuit diagram of the battery storage section 10.

FIG. 4 is a horizontal cross-sectional view of the terminal portion of the battery storage section 10. As shown in FIG.

FIG. 5 is a vertical cross-sectional view of the terminal portion of the battery storage section 10. As shown in FIG.

FIG. 6 is a left and right perspective view of the battery pack 20 according to the first embodiment of the present invention.

FIG. 7 is a schematic electrical circuit diagram of the battery pack 20.

FIG. 8 shows the overall appearance of the battery pack 20 when installed in the battery compartment 10.

FIG. 9 is a schematic electrical circuit diagram of the battery pack 20 when installed in the battery compartment 10.

FIG. 10 shows the old (or nearly over-discharged) battery pack 20 being removed to replace it with a new (or fully charged) battery pack 20'.

FIG. 11 is a schematic electrical circuit diagram showing the battery pack 20 shown in FIG. 10 in the middle of being removed.

FIG. 12 shows how to replace the old battery pack 20 with a new battery pack 20'.

FIG. 13 is a schematic electrical circuit diagram in the state shown in FIG.

FIG. 14 shows the new battery pack 20' fully installed in the battery compartment 10.

FIG. 15 is a schematic electrical circuit diagram in the state shown in FIG.

FIG. 16 is a perspective view of a battery compartment 10 according to a second embodiment of the present invention.

FIG. 17 is a horizontal cross-sectional view of the battery storage section 10 according to the second embodiment.

FIG. 18 is a diagram showing the state in which the old and new battery packs 20, 20′ are being exchanged in the battery storage section 10 according to the second embodiment.

FIG. 19 is an electrical circuit diagram showing a modified example of the battery pack 20 and battery compartment 10.

FIG. 20 shows the external configuration of the notebook computer (PC) 100.

FIG. 21 shows the PC 100 with the cover 120 and keyboard 113 open, exposing the internal structure of the main body.

FIG. 22 is a perspective view of the PC 100 seen from the left rear.

FIG. 23 shows a general configuration (prior art) of a power system for a notebook computer 100 equipped with a sub-battery.

[Explanation of Symbols] 10... Battery Compartment, 20... Battery Pack, 100... Personal Computer, 110... Main Unit, 111... Lower Casing, 112... Support Plate, 113... Keyboard/TrackPoint, 114... Speaker, 115... Tab, 115A... Indicator, 116... Partition, 117... HDD Pack, 118... CD-ROM Drive, 119... Battery Pack, 120... Lid, 121... Upper Casing, 122... Protrusion, 123... LCD, 124... Opening/Closing Operation, 201... AC Adapter, 202... Main Battery (Battery Pack), 203... AC/DC Switching Circuit/Main Battery Charging Circuit, 204... Main DC/DC Converter, 205... Main/Sub Power Supply Switching Circuit, 206... Sub Battery, 207: Sub-battery charging circuit, 208: Charge/discharge switching circuit, 209: Sub-DC/DC converter, 210: Power management processor, 211: System load.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. A. First Embodiment First, the configurations of a PC 100, a battery compartment 10, and a battery pack 20 according to a first embodiment of the present invention will be described with reference to Figures 1 to 7. Note that components that are substantially the same as those in Figures 20 to 23 are given the same reference numerals.

FIG. 1 shows the external configuration of a notebook PC 100 embodying the present invention. In this figure, the PC 100 is a lid-equipped structure similar to that described in the "Background Art" section and FIGS. 20 and 21, with the lid 120 and keyboard 113 open relative to the main body 110. The space in front of the main body 110, covered by the keyboard 113, is provided for accommodating removable devices such as a hard disk drive (HDD) pack, a floppy disk drive (FDD) pack, and a CD-ROM drive, as well as a battery pack (main battery) 20. In this example, the approximate center of the front space is used as the battery pack storage compartment 10.

FIG. 2 is an enlarged perspective view of the battery storage section 10. As shown in FIG.

The battery storage compartment 10 is defined on all four sides by a right side wall 10-1, a left side wall 10-2, a rear side wall 10-3, and a front side wall 10-4. The battery storage compartment 10 and battery pack 20 according to this embodiment have a multi-terminal structure with multiple positive and negative terminals (three positive terminals and two negative terminals). The right side wall 10-1 is the surface for engaging with the positive side of the battery pack and includes three terminals 10-a, 10-b, and 10-c. The left side wall 10-2 is the surface for engaging with the negative side of the battery pack and includes two terminals 10-d and 10-e. Each terminal 10-a, 10-b, etc. has a tongue-shaped recess formed therein, and a terminal (contact) is embedded approximately in the center of the recess (see below and Figures 4 and 5). The bottom edges of the front and rear side walls 10-3, 10-4 are curved in an arcuate shape to match the curved surfaces of the sides of the battery pack 20 (described below).

Figure 3 shows the electrical circuit of the battery compartment 10. The three positive terminals 10-a, 10-b, and 10-c and the two negative terminals 10-d and 10-e are each combined into a single power line leading to the DC/DC converter 204 within the PC 100. Reverse-current prevention diodes D1 and D2 are connected to each of the positive terminals 10-a and 10-c, with the forward direction being the direction of battery discharge.

When the battery pack 20 is fully installed and in contact with all positive terminals 10-a, 10-b, and 10-c, the internal resistance of diodes D1 and D2 causes discharge current to flow only through terminal 10-b (as described below). Furthermore, because diodes D1 and D2 are connected between terminals 10-a and 10-c with their cathodes facing each other, no current flows between the two terminals. D1 and D2 prevent short circuits between old and new batteries during replacement, as will become clear later in this document.

4 and 5 show horizontal and vertical cross sections of terminal portion 10-a of battery storage portion 10. It should be understood that the other terminal portions 10-b, 10-c, etc. have substantially the same structure.

The tongue-shaped recess has an opening 12 at approximately its center for exposing the terminal (contactor) 11. A chamber 13 for embedding the contactor is provided on the back side. The contactor 11 is a conductive component with a protrusion at approximately its center, and is made, for example, by pressing a thin, highly ductile metal piece. A spring 14 is disposed on the back side of the protrusion of the contactor 11, and the restoring force of the spring 14 urges the contactor 11 to protrude from the opening 12. A lead wire 15 is connected to one end of the contactor 11 by solder or other means for electrical connection with a predetermined electrical circuit (DC/DC converter 204).

FIG. 6 shows the external appearance of the battery pack 20 used in this embodiment from a left perspective view and a right perspective view.

The battery pack 20 has a flat, rectangular housing with front and rear sides 20-3 and 20-4 that are roughly semi-cylindrical, with a footprint slightly smaller than that of the battery compartment 10 described above. The housing is typically made of a durable, insulating material such as polycarbonate. The battery pack 20 has a multi-terminal structure, with three positive terminals 20-a, 20-b, and 20-c on its right side and two negative terminals 20-d and 20-e on its left side. Each terminal 20-a, 20-b corresponds to a terminal 10-a, 10-b in the battery compartment 10. The periphery of each terminal 20-a and 20-b is surrounded by an annular protrusion.

The annular protrusion is made of insulating material and is integrally formed with the battery pack 20 housing. Its outer diameter is slightly smaller than the width of the corresponding tongue-shaped recess in the battery compartment 10. The annular protrusion is used to lock the battery pack 20 into the battery compartment 10 (described below), and is also expected to prevent short circuits caused by contact with conductive foreign objects. The semi-cylindrical side surfaces 20-3 and 20-4 of the battery pack 20 are formed with approximately the same curvature as the side walls 10-3 and 10-4 of the battery compartment 10. As described below, the battery pack 20 is installed in a recessed manner within the battery compartment 10, but a ribbon 21 is attached to the top surface of the battery pack 20 to facilitate removal.

FIG. 7 shows a schematic electrical circuit diagram of the battery pack 20.

Battery pack 20 consists of multiple battery cells, such as NiCd or NiMH, connected in series (or parallel). The number of battery cells is determined based on the drive voltage and capacity required by the PC, and is not relevant to the gist of this invention.

The positive electrode side branches into three and is taken out from terminals 20-a, 20-b, and 20-c, respectively, and the negative electrode side branches into two and is taken out from terminals 20-d and 20-e, respectively.

Next, the operation of the first embodiment and the method of installing/replacing the battery pack 20 will be described with reference to FIGS. 8 to 15.

FIG. 8 shows an overview of the battery pack 20 when installed in the battery compartment 10.

As can be easily inferred from the above description, the battery pack 20 is installed by embedding it into the battery compartment 10, which is recessed beneath the keyboard of the PC main body 110. Terminals 20-a, 20-b on each side of the battery pack 20 engage with corresponding terminals 10-a, 10-b on the battery compartment 10. Each annular projection on the periphery of each terminal 20-a of the battery pack 20 has approximately the same width as the tongue-shaped recess formed on the corresponding terminal 10-a on the battery compartment 10 (as described above). During installation and removal, the annular projection must overcome the protrusion of the contact 11 against the restoring force of the spring 14. Once installed, the contact 11 projects into the inner ring of the annular projection, thereby locking the battery pack 20 in place.

FIG. 9 shows a schematic diagram of the electrical circuit when the battery pack 20 is installed in the battery compartment 10.

As shown in the figure, the positive side of battery pack 20 is electrically connected to the PC 100 main unit via terminals 20-a, 20-b, and 20-c, and its negative side is electrically connected via terminals 20-d and 20-e. Diodes D1 and D2 are inserted into positive terminals 20-a and 20-c, respectively, with the direction of the battery discharge current being the forward direction (as described above). Although all three positive terminals are electrically connected, due to the internal resistance of diodes D1 and D2 at the left and right terminals 20-a and 20-c, discharge current flows only through center terminal 20-b. Therefore, when battery pack 20 is properly installed and operating normally, there is no power loss due to the forward voltage drop of diodes D1 and D2, or the heat generation associated with power loss.

FIG. 10 shows the state in which an old (or nearly over-discharged) battery pack 20 is being removed in order to be replaced with a new (or fully charged) battery pack 20'.

The operator can remove the battery pack 20 from the battery compartment 10 by pulling the ribbon 21 attached to the top surface of the battery pack 20 in the direction of arrow P in the figure. At this time, the latching action between terminals 20-a and 10-a, 20-b and 10-b, and 20-d and 10-d closest to the ribbon 21 is released by the relatively strong torque generated by the pulling force P. Meanwhile, the torque between terminals 20-c and 10-c farther from the ribbon 21 is relatively small, so the latch is not released. Therefore, as shown in the figure, the battery pack 20 rotates around the axis connecting terminals 20-c (10-c) and 20-e (10-e) and stands upright. Since the front and rear side surfaces 20-3, 20-4 of the battery pack 20 are formed semicircularly, and the front and rear side walls 10-3, 10-4 of the battery storage section 10 are formed arcuately (as described above), the side surfaces 20-3, 20-4 slide smoothly over the surfaces of the side walls 10-3, 10-4 when the battery pack 20 is removed.

FIG. 11 is a schematic diagram of the electrical circuit when the battery pack 20 shown in FIG. 10 is in the process of being removed.

As shown in the figure, the battery pack 20 is electrically connected only at output terminals 20-c and 20-e. Therefore, the battery discharge current between these terminals flows forward through diode D2.

FIG. 12 shows the process of replacing the old battery pack 20 with a new battery pack 20'.

When the old battery pack 20 is placed upright, the terminals 10-a and 10-d are exposed, as shown in Figure 10. Then, as shown in Figure 12, the new battery pack 20' can be inserted into the battery compartment 10 from the rear semi-cylindrical side 10-3, i.e., the terminals 20-a and 20-d.

FIG. 13 shows a schematic diagram of the electrical circuit of the battery packs 20, 20′ in the state shown in FIG.

As shown in Figure 11, the old battery pack 20 is electrically connected at terminals 20-c and 20-e. The new battery pack 20' is electrically connected at terminals 20-a and 20-d, which were released from the old battery pack 20. Generally, when replacing a battery pack, the output terminal voltage and remaining capacity of the old and new battery packs 20 and 20' differ significantly. Therefore, if the positive terminals of the new and new batteries short-circuit, a large current may flow from one to the other, potentially causing serious damage to both.

However, in this embodiment, two reverse current prevention diodes D1 and D2 are inserted between the positive terminals of both battery packs 20 and 20' with their cathodes facing each other (as described above), so such an electrode short circuit does not occur.

FIG. 14 shows the new battery pack 20' being fully installed into the battery compartment 10.

First, the old battery pack 20 is pulled upward (not shown). At this time, a certain amount of force is required to release the latch between terminals 20-c and 10-c, and 20-e and 10-e. After the latches are released, the outer periphery of the annular protrusion is aligned with the side of the tongue-shaped recess, and the battery pack 20 is removed.

Next, a force in the direction Q in the figure is applied to the top of the new, upright battery pack 20'. This causes the battery pack 20' to rotate about the axis connecting the terminals 20-a (10-a) and 20-d (10-d) and collapse into the battery compartment 10. At this time, the semi-cylindrical side surface 20-4 of the battery pack 20' moves over the arcuate side wall 10-4 of the battery compartment, so the rotational force Q is relatively small.

The annular projections of terminals 20-c and 20-e then pass through the tongue-shaped recesses of terminals 10-c and 10-e, respectively, and overcome and engage with the contacts due to the rotational force Q and the weight of battery pack 20'. Battery pack 20' then returns to the installed state shown in Figures 8 and 9, completing the replacement procedure.

FIG. 15 is a schematic electrical circuit diagram in the state shown in FIG.

As shown in the figure, battery pack 20' is electrically connected only at output terminals 20-a and 20-d. Therefore, the battery discharge current between these terminals flows forward through reverse mixing prevention diode D1.

As can be easily understood from the above explanation, power to PC 100 is not interrupted at any stage in Figures 9, 11, 13, and 15. This allows PC 100 to continue operating without any particular changes, completely protecting volatile data.

In each of the states shown in Figures 11, 13, and 15, the battery discharge current flows through one or both of diodes D1 and D2. However, in reality, this situation only occurs temporarily during the short time required for battery pack replacement. With the battery pack fully installed, as shown in Figure 9, the discharge current flows only through output terminal 20-b, which does not involve a diode, and therefore, problems associated with the forward voltage drop caused by diodes D1 and D2 are virtually eliminated.

Although not precisely depicted in Figures 2 and 6, the outer diameter of each annular protrusion on the battery pack 20 and the width of each tongue-shaped recess on the battery compartment 10 are dimensionally different for each corresponding combination. This prevents the battery pack 20 from being installed in any orientation other than the specified orientation.

Also, as shown in Figures 3 and 7, in this embodiment, the backflow prevention diodes D1 and D2 are provided on the battery storage section 10 side, but as shown in Figure 19, they may be provided inside the battery pack 20. In this case, the number of wires between the battery storage section 10 and the PC 100 main body can be reduced. B. Second Embodiment It should be clear from Section A that according to the first embodiment, the battery pack 20 can be replaced without interrupting the power supply to the PC 100, and that a sub-battery is not required for backup during replacement.

However, in the first embodiment, as shown in Figure 10, an operator can remove battery pack 20 even when power is being supplied only from battery pack 20. This is because, although battery pack 20 is retained by the latching action between the annular projections and the contacts at terminals 20-c and 20-e (as described above), the holding force of this latch is relatively weak. This means that an impatient operator may mistakenly perform the replacement procedure and completely remove old battery pack 20 before it is backed up by new battery pack 20', as shown in Figure 12, causing a power outage.

The second embodiment is directed to a mechanism (a "foolproof" mechanism) for preventing simultaneous removal of the old and new battery packs 20.

16 and 17 are a perspective view and a horizontal cross-sectional view of the battery storage section 10 according to the second embodiment. Note that omitted parts not shown in these figures and the battery pack 20 are understood to be substantially the same as the corresponding parts of the first embodiment.

As shown in Figure 17, a chamber for accommodating a lever 31 is formed on the back side of the right side wall 10-1 of the battery compartment 10. The lever 31 is a generally L-shaped component with a latch 34 formed at one end. The other end of the lever 31 is rotatably supported by a fulcrum 33 and is biased by a spring 32 in the rotational direction indicated by arrow R in the figure. This biasing force causes the latch 34 to protrude from an opening formed in the terminal portion 10-c toward the surface of the battery compartment 10 (see Figure 16). The end face of the latch 34 is shaped to engage with the outer peripheral surface of the annular protrusion on the battery pack 20, providing a much stronger latching effect than the contact 11, which has a relatively gently curved surface (described below). A plunger 35 with a tapered tip abuts approximately the center of the lever 31. The plunger 35 is pressed from its rear surface by the lever 31, and its tapered tip protrudes from an opening formed near the terminal portion 10-a (FIG. 16).

Although not shown in FIGS. 16 and 17, it should be understood that a similar foolproof mechanism is also provided on the left side wall 10-2 of the battery compartment.

FIG. 18 shows the state in which the old and new battery packs 20, 20' are being exchanged in the battery storage section 10 according to the second embodiment.

When the new battery pack 20' has not yet been installed or is in the middle of being installed and is in a generally upright position (Figure 18), the tip of plunger 35 is released, and lever 31 receives a rotational force in the direction of arrow R from spring 32 alone. As a result, latch 34 engages with the annular projection on terminal 20-c of the old battery pack 20, locking it in place with a relatively strong force to prevent removal.

Meanwhile, as the new battery pack 20' is tilted, the edges of its left and right side surfaces 20-1 and 20-2 come into contact with the plunger 35. The tip of the plunger 35 is tapered (as described above), and as the battery pack 20' is tilted, it is pushed by the edges of the left and right side surfaces 20-1 and 20-2, gradually pushing it back in the direction of arrow S in Figure 17. Accordingly, the lever 32 rotates in the direction of arrow S, and the latch 34 retracts. As a result, the locking state that had been applied to the annular protrusions of the terminals 20-c and 20-e is released, allowing the old battery pack 20 to be removed.

While the foolproof mechanism is disposed in the battery compartment 10 in this example, it is of course also possible to incorporate it in the battery pack 20. C. Supplement The present invention has been described in detail above with reference to specific embodiments. However, it is obvious that those skilled in the art can modify or substitute the embodiments without departing from the spirit and scope of the present invention. For example, the present invention can also be applied to battery-powered electrical and electronic devices such as facsimile machines, mobile wireless terminals, cordless telephones, electronic organizers, various cordless devices such as video cameras, word processors, etc. In short, the present invention has been disclosed in the form of examples and should not be interpreted in a limiting sense. To determine the spirit and scope of the present invention, the claims set forth at the beginning of this specification should be taken into consideration.

[Industrial Applicability] The present invention provides an excellent battery storage device and battery pack that can be used in battery-powered electrical and electronic devices such as notebook computers, facsimile machines, mobile radio terminals, cordless telephones, electronic organizers, various cordless devices such as video cameras, and word processors.

The battery storage device and battery pack according to the present invention allow the battery pack to be replaced without interrupting the power supply to the electrical and electronic devices.

Furthermore, auxiliary power sources such as sub-batteries can be completely eliminated, allowing for a single power system including the DC/DC converter and charging circuit.

This simplifies the electrical circuitry within the system, saving space inside the enclosure and reducing costs.

───────────────────────────────────────────────────── Continued from the front page (72) Inventor: Mitsuo Horiuchi 1623-14 Shimotsuruma, Yamato City, Kanagawa Prefecture, Japan IBM Japan, Inc., Yamato Business Office (72) Inventor: Mitsuru Ogawa 1623-14 Shimotsuruma, Yamato City, Kanagawa Prefecture, Japan IBM Japan, Inc., Yamato Business Office (Note) This publication is based on the publication published internationally by the International Bureau of Patents (WIPO). The effect of the international publication of the Japanese patent application (Japanese utility model registration application) related to this publication arises pursuant to Article 184-10, Paragraph 1 of the Patent Act (Article 48-13, Paragraph 2 of the Utility Model Act) and is unrelated to this publication.

Claims (11)

[Claims] 1. A battery storage device for use in battery-powered electrical and electronic devices, characterized by including multiple positive terminals and multiple negative terminals. 2. A battery storage device for use in a battery-powered electrical or electronic device, comprising a plurality of positive terminals and a plurality of negative terminals, and having a first mounting state in which the battery is connected via one set of positive and negative terminals, a second mounting state in which the battery is connected via another set of positive and negative terminals, a third mounting state that combines the first and second mounting states, and a fourth mounting state in which the battery is connected via all of the positive and negative terminals. 3. The battery storage device according to claim 2, further comprising a locking mechanism that prevents the battery from being removed in the first mounting state. 4. The battery storage device according to claim 3, wherein the locking mechanism permits removal of the battery in the fourth mounting state. 5. A battery storage device for use in a battery-powered electrical or electronic device, having a shallow bottom, with multiple positive terminals arranged on a first side wall and multiple negative terminals arranged on a second side wall opposite the first side wall. 6. A battery storage device for use in a battery-powered electrical or electronic device, characterized in that it has a shallow bottom, a plurality of positive terminals arranged on a first side wall, and a plurality of negative terminals arranged on a second side wall opposite the first side wall, and is capable of connecting to one battery via one set of positive and negative terminals and to another battery via another set of positive and negative terminals. 7. The battery storage device according to claim 6, further comprising a locking mechanism that prevents removal of the battery when only one battery is connected by one set of positive and negative terminals. 8. The battery storage device according to claim 7, further comprising: detection means for detecting connection to another battery via another set of positive and negative terminals; and unlocking means for unlocking the locking mechanism in response to the detection result from the detection means. 9. A battery storage device for use in a battery-powered electrical or electronic device, comprising three first electrode terminals connected in parallel and two parallel electrode terminals having polarities opposite to those of the first electrode terminals, wherein backflow prevention elements are inserted into two of the first electrode terminals. 10. A battery pack for use in a battery-powered electrical or electronic device, comprising a plurality of positive terminals and a plurality of negative terminals. 11. A battery pack for use in a battery-powered electrical or electronic device, having a flat, oblong shape, with a substantially semi-cylindrical side surface, a first end face including three positive terminals, and a second end face facing the first end face and including two negative terminals.