JPH0617338U - Charger - Google Patents

Abstract

(57) [Summary] [Purpose] To prevent the temperature rise of the secondary battery during charging and prevent the harmful effects of high temperature of the battery. [Structure] A charger includes a casing 1 to which a secondary battery 2 is detachably connected, and a charging circuit incorporated in the casing 1. The high heat-generating component 3 built in the casing 1 is arranged apart from the secondary battery 2. A contact support member 5 that supports a charging contact 4 connected to a battery contact of the secondary battery 2 is disposed between the high heat generating component 3 and the secondary battery 2, and the contact support member 5 and the secondary battery 2 are connected to each other. It is also used as a heat shielding material for the heat generating component 3. [Effect] The secondary battery is thermally shielded from the high heat-generating component by the contact support member, and the deterioration of the battery performance due to the temperature during charging can be suppressed.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a rechargeable battery charger, and more particularly to a rechargeable battery charger that can charge a rechargeable battery in a short time.

[0002]

[Prior art]

 The charger contains a charging circuit inside the casing. The casing detachably connects the secondary battery. When the secondary battery is set in the casing, the charging circuit is connected to the secondary battery via the contacts. The charging circuit converts the input alternating current into a charging voltage for the secondary battery, controls the charging current to an appropriate value, and supplies the charging current to the secondary battery. To achieve this, the charging circuit requires heating components. For example, a control element that controls the state of charge, a diode that rectifies alternating current to direct current, and the like generate heat when charging a secondary battery. In addition, recent chargers have a built-in inverter circuit to reduce size and weight. The charging circuit that incorporates an inverter circuit can reduce the size and weight of a heavy transformer by increasing the oscillation frequency. This charging circuit converts the input AC into DC without converting the voltage and drives the inverter circuit. The output of the inverter circuit is rectified and then converted back to direct current. In the charger having such a structure, the heat generating component is arranged near the secondary battery. This is because the heat generating component is on the output side of the charging circuit.

[0003]

[Problems to be solved by the device]

 In the charger in which the heat generating component is arranged close to the secondary battery, the charging control circuit that is the heat generating component can be connected to the secondary battery in the shortest distance. However, the charger having this structure has a drawback that the temperature of the battery rises when the secondary battery is charged. This is because the heat-generating component is arranged close to the secondary battery and below the secondary battery. The temperature rise during charging adversely affects secondary batteries such as nickel-cadmium batteries and nickel-hydrogen batteries. In particular, nickel-metal hydride batteries, whose usage has increased rapidly in recent years, release gas when the temperature rises during charging, degrading battery performance. In order to prevent this problem, nickel-metal hydride batteries use a charger that detects the battery temperature during charging, suspends charging when the temperature rises, and starts charging again when cooled. When this type of charger charges a secondary battery that is sensitive to temperature rise, the temperature rise of the secondary battery significantly extends the charging time. Especially, the charging time becomes longer in the summer. For example, if a nickel-hydrogen battery is charged with a charger that incorporates heat-generating components such as an inverter circuit and a charge control circuit below the secondary battery, and charging is suspended several times during charging, the charging time will be Compared with continuous charging, it will be several times longer. Not only nickel-metal hydride batteries, but also nickel-cadmium batteries, etc., it is important to reduce the temperature rise during charging to reduce the deterioration of battery performance due to temperature. Chargers tend to be progressively smaller as they become more difficult to design. Packing heat-generating components in a small casing is restricted by increasing the heat dissipation area, which causes the temperature of the secondary battery to rise.

The present invention was developed to solve the drawbacks of conventional chargers. Therefore, the important purpose of this invention is to limit the temperature rise of the secondary battery to a low level to prevent the deterioration of the battery performance due to the temperature of the secondary battery during charging, and to use the contact support member as a heat shield. The purpose is to provide a charger that can be used together with a simple structure.

[0005]

[Means for Solving the Problems]

 The battery charger of the present invention has the following structure to achieve the above-mentioned object. That is, the charger of the present invention comprises a casing 1 to which the secondary battery is detachably connected, and a charging circuit built in the casing 1 to charge the secondary battery 2. The charging circuit includes a high heat generating component 3. The high heat-generating component 3 built in the casing 1 is arranged apart from the secondary battery 2. Further, in the charger of the present invention, a contact support member 5 that supports a charging contact 4 connected to the battery contact of the secondary battery 2 is disposed between the high heat generating component 3 and the secondary battery 2 to support the contact. The member 5 is used as a heat shielding material for the secondary battery 2 and the high heat generating component 3.

[0006]

In the charger of the present invention, the arrangement of the high heat-generating component 3 contained in the casing 1 is changed from that of the conventional one. That is, in the conventional charging circuit, the high heat-generating component 3 that supplies the charging current to the secondary battery 2 is arranged close to the secondary battery 2. On the other hand, in the charging circuit of the present invention, the high heat generating component 3 is arranged away from the battery. The charger having this structure can reduce heating of the secondary battery 2 by the heat generated by the high heat-generating component 3.

Further, a contact blocking member 5 that supports a charging contact 4 connected to a battery contact of the secondary battery 2 is also used as a heat blocking member that thermally blocks the secondary battery 2 from the high heat generating component 3. ing. Therefore, it is not necessary to specially provide a heat shielding material for heat.

[0008]

【Example】

 Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments shown below exemplify a charger for embodying the technical idea of the present invention, and the charger of the present invention is composed of materials, shapes, arrangements, electric circuits, etc. of components. Are not specified below. The charger of the present invention can be modified in various ways within the scope of the utility model registration claim.

The charger shown in FIGS. 1 to 4 includes a charging circuit 4 inside a casing 1. The casing 1 is provided on both sides of the upper surface with a detachable portion 1A into which the secondary battery 2 can be slid and inserted in the horizontal direction indicated by an arrow. The detachable portion 1A has protrusions 7 for guiding the slide grooves 6 of the secondary battery 2 on both inner surfaces, and a pressing piece 8 for elastically pressing the concave portion on the lower surface of the secondary battery 2 is provided on the bottom surface. There is. Further, a locking piece 9 for locking the battery is projected so as to project on one inner surface of the detachable portion 1A. When the button 10 provided on the casing 1 is pressed, the locking piece 9 is pulled in from the inner surface of the attachment / detachment portion to release the locked state of the secondary battery 2.

The battery contact of the secondary battery 2 set in the detachable portion of the casing 1 contacts the charging contact 4 fixed to the contact support member 5. The charging contact 4 of the contact support member 5 penetrates the window 19 of the casing 1 and projects to the detaching portion to come into contact with the battery contact of the secondary battery 2. The charging contact 4 is connected to the charging circuit.

The charging circuit 4 is shown in the block diagram of FIG. This charging circuit includes a noise prevention circuit 11, a primary rectifying circuit 12, an inverter circuit 13, a secondary rectifying circuit 14, and a charging control circuit 15.

The noise prevention circuit 11 prevents noise generated in the charging circuit from leaking to the outside through the power cord, and is composed of a coil L ₁ and a capacitor C _{1 as} shown in FIG. It The primary rectifier circuit 12 includes a diode D ₁ that rectifies an alternating current of an input commercial power source and a large-capacity electrolytic capacitor C ₂ that smoothes the rectified pulsating current.

[0013] The inverter circuit 13 includes a switching transistor Q _1, a transformer T connected to the switching preparative lunge star Q _1, an oscillation circuit IC ₁ for inputting a rectangular wave to a gate of the switching transistor Q _1. The inverter circuit 13 turns on and off the switching transistor Q ₁ to flow a rectangular wave on the primary side of the transformer T. The switching transistor Q ₁ is turned on / off by the rectangular wave input from the oscillator circuit IC ₁ . The transformer T converts the input voltage on the primary side and outputs it to the secondary side. The inverter circuit 13 includes a stabilizing circuit that detects the output voltage and controls the output voltage to be constant. The switching transistor Q ₁ of the inverter circuit 13 is a heating element.

The secondary rectifier circuit 14 includes a diode D ₂ that rectifies the secondary output of the transformer T, and a capacitor C ₃ that smoothes the rectified pulsating flow. This capacitor C ₃ can have a smaller capacity than the capacitor C ₁ . This is because the inverter circuit 13 converts the input direct current into an alternating current having a high frequency of several tens kHz to several hundreds kHz. The diode D ₂ of the secondary rectification circuit 14 rectifies a large current and thus serves as a heating element.

The charging control circuit 15 controls the DC output of the secondary rectifier circuit 14 and supplies the DC power to the secondary battery 2. Therefore, the charging control circuit 15 includes a control transistor Q ₂ that controls the charging current. The control transistor Q ₂ is controlled by the control circuit IC ₂ . The charge control circuit 15 detects the charge amount of the battery and adjusts the charge current, or detects the temperature of the battery and controls the charge state. For example, the charge control circuit 15 stops charging when the battery is fully charged, or stops charging when the temperature of the battery rises above a set value, and restarts charging when the temperature drops.

Further, the output side of the charge control circuit 15 is preferably provided with a discharge circuit 16 for forcibly discharging the battery. The discharge circuit 16 is composed of a resistor R ₁ and a switching element Q ₃ connected in series. The switching element Q ₃ is controlled by the control circuit IC ₂ . The discharge circuit 16 is connected in parallel with the secondary battery 2. When the switching element Q ₃ of the discharge circuit 16 is turned on, the secondary battery 2 is forcibly discharged by the discharge resistor R ₁ . When the secondary battery 2 is discharged to the set voltage, the switching element Q ₃ turns off and stops discharging. The switching element Q ₃ and the discharge resistor R ₁ of the discharge circuit 16 are heating elements.

The charger shown in FIG. 3 has components constituting a charging circuit attached to a printed circuit board 17. The printed circuit board 17 is horizontally fixed to the bottom of the casing 1. In the charger shown in this figure, a high heat-generating component 3 having a large heat generation amount is arranged between the secondary batteries 2, that is, in the central portion of the printed circuit board 17, as shown in FIG. High heating unit article 3 is a large part of the large amount of generated heat power consumption in the charging circuit shown in FIG. 3, the switching transistor Q _1, a transformer T connected to the switching transistor Q _1, a transformer T A diode D ₂ for rectifying the secondary output, a control transistor Q ₂ for controlling the charging current, a discharge resistor R _1, and a switching element Q ₃ .

Components that generate a small amount of heat, for example, the components that constitute the noise prevention circuit 11 and the primary rectifier circuit 12, and the smoothing capacitor C ₃ are located below the secondary battery 2 and are located on the printed circuit board. It is fixed at 17.

On the printed circuit board 17, the contact support members 5 are vertically disposed between the high heat generating component 3 and the secondary battery 2 on both sides of the high heat generating component 3. The contact support member 5 is a base that supports the charging contact 4 connected to the charging circuit, and a heat blocking material that thermally blocks the secondary battery 2 and the high heat-generating component 3. The contact support member 5 shown in FIG. 2 is designed to have a height extending from the printed board 17 to the top plate of the casing 1 as shown in FIG. 3, and has a width as shown in FIGS. 2 and 4. The width of the secondary battery 2 is set to be almost equal. That is, in the charger shown in FIG. 4, the width of the contact supporting member 5 is narrower than the inner width of the casing 1 and is designed to be substantially the width of the secondary battery 2. In the figure, the right side of the lower contact support member 5 and the left side of the upper contact support member 5 are heat passages, and the heat passing through these passages is exhausted through the top plate of the casing 1. Therefore, the top plate of the casing 1 has air holes 18 for exhaust air provided on the right side of the lower attaching / detaching portion for setting the secondary battery 2 and on the left side of the upper attaching / detaching portion. As shown in FIG. 2, the casing 1 also has an air hole 18 opened in the bottom plate so that the air can be effectively exhausted from the air hole 18.

As shown in FIG. 2, the contact support member 5 has fixed leg portions 5A on both sides of the vertical plate. The fixed leg portion 5A penetrates the printed board 17 to fix the contact support member 5 to the printed board 17. The charging contact 4 is vertically fixed to the vertical plate. The charging contact 4 penetrates the printed circuit board 17 at the lower end of the vertical plate, and the upper part is bent in a U shape. The lower end that penetrates the printed circuit board 17 is soldered to the wiring of the printed circuit board 17. The U-shaped upper end portion penetrates the window 19 opened in the casing 1 and projects to the attachment / detachment portion 1A of the secondary battery 2.

The charger shown in FIGS. 1 to 4 is provided with a detachable portion 1A for setting the secondary battery 2 of two turns. The charger having this structure can charge the secondary battery 2 of two volumes at the same time, or can charge the secondary battery 2 of the next after the charging of the secondary battery 2 of one volume is completed. For a charger that charges two rechargeable batteries together, the charging circuit is provided with two sets of charging control circuits. The charging circuit for charging the secondary battery 2 one turn at a time is provided with a switching circuit to switch the secondary battery to be charged after the charging is completed.

The charger shown in FIG. 7 includes a detachable portion 1A for setting the secondary battery 2 of one roll. This charger has a high heat-generating component 3 built in on the right side of the casing 1, and an attaching / detaching part 1A for setting the secondary battery 2 on the upper left side of the casing 1. A contact support member 5 is vertically disposed between the detachable portion 1A of the secondary battery 2 and the high heat-generating component 3, and the secondary battery 2 is thermally separated from the high heat generating component 3 by the contact supporting member 5. It is shut off. In the charger shown in this figure, the structure of the contact support member 5 is the same as that of the charger shown in FIGS. 1 to 4.

[0023]

[Effect of device]

 The battery charger of the present invention has a feature that the temperature rise of the secondary battery to be charged can be reduced and the adverse effects of the high temperature of the secondary battery can be reduced. The temperature of the secondary battery rises when the charging current is increased and it is charged rapidly in a short time. Furthermore, in a charger that charges rapidly, the charging current increases and the temperature of the charging circuit also rises. In the battery charger of the present invention, the high heat generating component built into the casing is arranged apart from the secondary battery, and the heat shielding material is disposed between the secondary battery and the high heat generating component. The heat generated by the high heat-generating parts does not heat the secondary battery so much that the temperature rise of the secondary battery can be suppressed and charging is possible. For this reason, the charger of the present invention effectively prevents the battery from being heated to a high temperature and deteriorating the battery performance during charging, and adverse effects due to the temperature, for example, shortening the life or reducing the capacity. It has the feature that it can prevent the harmful effects such as decrease.

Furthermore, a remarkable feature of the present invention is that the contact support member for fixing the charging contact is also used as the heat shield material to simplify the structure, reduce the number of parts, and improve the production efficiency. It can be improved. Particularly preferably, since the contact support member is a base for fixing the charging contact that energizes the battery contact of the secondary battery, it is arranged close to the secondary battery. Therefore, by using the contact support member together with the heat shield and arranging it between the high heat-generating component and the secondary battery, the heat shield is placed in an ideal position. To be done. Therefore, the contact support member effectively cuts off the heat generated by the high heat-generating component, and realizes the feature that the temperature rise of the secondary battery during charging can be suppressed.

The charger having this structure is most suitable for charging a nickel-hydrogen battery or the like that is sensitive to temperature rise, and has the feature that this type of battery can be charged with reduced battery performance due to high temperatures. Nickel-metal hydride batteries, which are susceptible to temperature rise, stop charging when the temperature rises, wait until they cool down, and then start charging again, a type of so-called charging-pausing-charging-pausing ... A charger is used. If the battery temperature rises during charging, this type of charger takes a considerable amount of time to suspend charging and cool the battery. Therefore, the temperature rise of the battery prolongs the charging time. When the charger of the present invention is used for this type, the temperature of the battery does not rise and the cooling time can be shortened and the charging time can be remarkably shortened.

[Brief description of drawings]

FIG. 1 is a perspective view of a charger showing an embodiment of the present invention.

FIG. 2 is an exploded perspective view of the charger shown in FIG.

FIG. 3 is a vertical sectional view of the charger shown in FIG.

FIG. 4 is a plan view of the charging contact shown in FIG.

FIG. 5 is a block diagram showing an example of a charging circuit.

6 is a circuit diagram of the charging circuit shown in FIG.

FIG. 7 is a sectional view of a charger showing another embodiment of the present invention.

[Explanation of reference numerals] 1 ... Casing 1A ... Removable part 2 ... Secondary battery 3 ... High heat-generating part 4 ... Charging contact 5 ... Contact support member 5A ... Fixed leg 6 ... Slide groove 7 ... Protrusion 8 ... Pressing piece 9 ... Engagement Stopper 10 ... Button 11 ... Noise prevention circuit 12 ... Primary rectification circuit 13 ... Inverter circuit 14 ... Secondary rectification circuit 15 ... Charge control circuit 16 ... Discharge circuit 17 ... Printed circuit board 18 ... Air hole 19 ... Window

Claims (1)

[Scope of utility model registration request] 1. A casing for removably connecting a secondary battery, and a charging circuit built in the casing for charging the secondary battery, wherein the charging circuit includes a high heat-generating component that generates a large amount of heat, The built-in high heat-generating component is a charger that is placed away from the secondary battery.In the charger, the contact support that supports the charging contact that connects to the battery contact of the secondary battery A charger characterized in that a member is provided and a contact support member is used as a heat shielding material for a secondary battery and a high heat generating component.