Electricity: electrothermally or thermally actuated switches – Electrothermally actuated switches – Fusible element actuated
Reexamination Certificate
2001-05-01
2003-05-20
Vortman, Anatoly (Department: 2835)
Electricity: electrothermally or thermally actuated switches
Electrothermally actuated switches
Fusible element actuated
C337S182000, C337S153000, C337S160000, C337S295000, C337S416000
Reexamination Certificate
active
06566995
ABSTRACT:
BACKGROUNG OF THE INVENTION
1. Field of the Invention
The present invention relates to a protective element wherein a heat-generating member generates heat under abnormal circumstances, which causes a low melting metal member to blow out.
2. Description of the Related Art
Protective elements comprising heat-generating members and low melting metal members layered on a substrate are known to be able to prevent overvoltages as well as overcurrents (e.g. Japanese Patent No. 2790433 and Japanese Patent Application Laid-open No. H8-161990). Such protective elements contain heat-generating members through which electricity is passed in abnormal circumstances, and the heat generated by these members melts the low melting metal. The surface of the electrode on which the low melting metal member is disposed is thereby wetted, which causes the low melting metal member to blow out.
FIG. 1
is a circuit diagram showing an example of an overvoltage-preventing device which utilises such a protective element
1
p
.
FIGS. 2A and 2B
shows respectively a plane view and a sectional view of the protective element
1
p.
The protective element
1
p
has a structure comprising heat-generating members
3
, on which a resist paste has been applied, an insulating layer
4
, and a low melting metal member
5
comprising a fuse material, all of which are layered on a substrate
2
. In the drawings,
6
a
and
6
b
are electrodes for the heat-generating members; the electrode
6
b
is connected to an electrode in the central portion of the low melting metal member
5
(intermediate electrode
7
c
), with the connection site being situated between two sites
5
a
and
5
b
into which the low melting metal member
5
has been divided.
7
a
and
7
b
are electrodes for the low melting metal member.
8
is a internal sealing component made from solid flux, with which the low melting metal member
5
is sealed to prevent its surface from oxidising, and
9
is an external sealing component comprising a material which has higher melting and softening points than the low melting metal member
5
and which prevents the molten low melting metal member
5
from flowing out of the protective element once it has blown out.
In the overvoltage preventing device shown in
FIG. 1
, which uses the protective element
1
p
, terminals A
1
and A
2
are connected to electrode terminals on the device to be protected; e.g. a lithium-ion battery, while terminals B
1
and B
2
are connected to electrode terminals of devices such as a charging device connected to the device to be protected. According to the overvoltage preventing device, when the charging of the lithium-ion battery proceeds and an overvoltage that is larger than the breakdown voltage is applied to a Zehner diode D, an abrupt base current i
b
will flow and cause a large collector current i
c
to flow through the heat-generating members
3
and thereby cause the heat-generating members
3
to heat up. This heat is transmitted to the low melting metal member
5
on the heat-generating members
3
, causing the two sites
5
a
and
5
b
of the low melting metal member
5
to blow out. This prevents any overvoltage from being applied to the terminals A
1
and A
2
and simultaneously interrupts the current flowing to the heat-generating members
3
.
An example of an embodiment of connection between the low melting metal member and heat-generating member in such types of protective elements is taught in Japanese Patent Application Laid-Open No. H10-116549 and Japanese Patent Application Laid-Open No. H10-116550, wherein the low melting metal member and the heat-generating member are connected while being disposed in planar fashion on the substrate, instead of the low melting metal member being layered on top of the heat-generating member. Nevertheless, the merit of having the flow of electricity to the heat-generating member being interruptible at the same time that the low melting metal member blows out remains the same.
Similarly to the protective element
1
p
shown in
FIG. 1
,
FIGS. 3A
,
3
B and
3
C depict respectively a plane view (
3
A) and sectional views (
3
B,
3
C) of a protective element
1
q
, in which the heat generated from a flow of electricity passing through a heat-generating member
3
causes a low melting metal member
5
to blow out and the flow of electricity destined for the heat-generating member
3
to be simultaneously interrupted (Japanese Patent Application No. H11-110163). Low melting metal member electrodes
7
a
,
7
b
and
7
c
are furnished on a substrate
2
in this protective element
1
q
, and a low melting metal member
5
(
5
a
,
5
b
) is disposed so as to bridge these electrodes
7
a
,
7
b
and
7
c.
A heat-generating member
3
is furthermore furnished on the underside of the electrode
7
c
, with an insulating layer
4
interposed therebetween. The heat-generating member
3
is heated by the flow of electricity passed between the heat-generating member electrode
6
b
and the leads
6
x
and
6
y
coming from the heat-generating member electrode
6
a
. The heat-generating member electrode
6
b
is connected to the low melting metal member electrode
7
c.
Accordingly, the heat generated by the heat-generating member
3
causes both the low melting metal member
5
a
between the electrodes
7
a
and
7
c
and the low melting metal member
5
b
between the electrodes
7
b
and
7
c
to blow out, and thereby interrupt the flow of electricity passed to the device to be protected, while also interrupting the flow of electricity transmitted to the heat-generating member
3
.
However, even if the heat generated by the heat-generating member
3
melts the low melting metal member
5
in the aforedescribed conventional protective elements
1
p
and
1
q
, the drawback arises that if the surface areas of the low melting metal member electrodes
7
a
,
7
b
and
7
c
are too narrow, the molten low melting metal member
5
will not flow sufficiently onto these electrodes and the low melting metal member
5
shall not blow out.
The drawback will also arise, moreover, that if the distance between adjacent electrodes (inter-electrode distance) with the low melting metal member
5
interposed therebetween is too small, the low melting metal member will not blow out despite being melted by the heat generated by the heat-generating member
3
has melted it. Conversely, if the inter-electrode distance is too great, the heat generated when the low melting metal member
5
has been connected to the substrate
2
will create a drawback that the low melting metal member
5
will become thin in specific areas, and moreover, the anti-pulse property will diminish whether or not the resistance value remains constant. Last, another drawback will arise when the inter-electrode distance is further increased, as the low melting metal member
5
will blow out when it is bonded to the substrate by thermocompression or the like.
SUMMARY OF THE INVENTION
With the foregoing problems in view, it is an object of the present invention to provide a protective element comprising a heat-generating member and a low melting metal member on a substrate, in which the low melting metal member is molten by the heat generated by the heat-generating member and flows onto electrodes, the low melting metal member being thereby caused to blow out, wherein the manufacturing stability and reliability of the protective element is enhanced by optimising both the surface area and the inter-electrode distance of the electrodes to which the molten low melting metal member flows when the heat is generated by the heat-generating member.
In achieving the aforedescribed object, the present invention provides a protective element comprising a heat-generating member and a low melting metal member on a substrate, in which the low melting metal member is molten by the heat generated by the heat-generating member and flows onto electrodes, whereby the low melting metal member is blown out, the protective element being characterised in that Formula (1) below is satisfied for at least one
Furuuchi Yuji
Kawazu Masami
Sony Chemicals Corporation
Vortman Anatoly
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