TWI638498B - Secondary battery pack and its protective component - Google Patents

Abstract

Secondary battery pack and its protective components. Protection components include overcurrent protection components, switches Components and heat generating components. An overcurrent protection component provides a first bidirectional current path between the first input and output of the protection component and the second input and output. When the current flowing through the first bidirectional current path is abnormal, the first bidirectional current path is turned off for overcurrent protection. The initial state of the switching element is an open state, and is coupled between the first input and output ends of the protection element and the third input and output end. A first end of the heat generating component is coupled to one end of the overcurrent protection component. When the heat generating component generates heat, the overcurrent protection component opens the first bidirectional current path, and the switching element is switched to the short circuit state to provide a second bidirectional current path between the first input and output terminals and the third input and output terminal. Thereby, the secondary battery pack and the protection element thereof of the present invention have an overcurrent, overvoltage or overtemperature protection function, and can save resources.

Description

Secondary battery pack and its protective component

The present invention relates to a secondary battery pack and a protective element thereof, and more particularly to a secondary battery pack having a function of overcurrent, overvoltage or overtemperature protection and resource saving and a protective element thereof.

Referring to FIG. 1A and FIG. 1B, FIG. 1A and FIG. 1B are circuit diagrams of a secondary battery 1101 and 1102 mentioned in Taiwan Patent No. TW I233228. The protective element of the secondary battery 1101 is composed of two fuse elements 1121, 1122 (or fuse elements) connected in series with a heater 1123 (heat generating resistor). One end of the heater 1123 (heat generating resistor) connects the end points 111c to which the two fuse elements 1121, 1122 are connected to each other. The protective element of the secondary battery 1102 is composed of a fuse element 1122 (or a fuse element) and a heater 1123 (or a heat generating resistor). One end of the heater 1123 (or the heat generating resistor) is connected to an end point 111a of the fuse element 1122 and the power storage device 1111.

In addition, please refer to FIG. 2 below, such as the protection element 2005 in the protection circuit 2001 in the battery pack 2002 mentioned in Taiwan Patent Certificate No.: TW 201517433 A. The protection element 2005 is composed of a fusible conductor 2016 (or fuse element) and a heating element 2012 (or a heating resistor). One end of the heating element 2012 (or the heating resistor) is connected to an end point 2013 where the fusible conductor 2016 is connected to the battery unit 2003.

Further, the battery pack 2 has a protection circuit 2001 in which a plurality of battery cells 2003 are connected in series, and the protection element 2005 is provided only on the charge and discharge path. If a part of the battery unit 2003 When an abnormality occurs and the protection element 2005 is operated, the charge and discharge path in the battery pack 2002 is blown, and the battery pack 2002 cannot continuously supply power. In this way, although the safety of the battery pack 2002 can be protected, since the battery unit 2003 is abnormal, the entire battery pack 2002 is disabled, so that the cost of the battery pack 2002 cannot be reduced or the maintenance cost is increased. In particular, many electronic products, electric motors, electric bicycles, and electric vehicles have recently demanded more power or current. Most of the current technologies require high voltage and high current or large power by serially connecting a plurality of battery units 2003 in series. Therefore, by using the above technique, if any of the battery cells 2003 is abnormal, the other plurality of normal battery cells 2003 cannot be used any more, which is a waste of resources.

In view of the improvement of the above disadvantages, the present invention provides a secondary battery pack and a protective component, in which a plurality of battery component groups are connected in series and in parallel to achieve a high voltage and a large current or a large power in a secondary battery pack, if any of the battery components When the group is overcharged or overvoltage or overtemperature, the protection component will disconnect the charging and discharging path of the abnormal battery component group, and switch the charging and discharging path to other normal battery component groups, in addition to overcharge or overvoltage or The function of over-temperature protection does not make other normal battery component groups unusable, so waste of resources can be avoided. When the charge and discharge current exceeds the rated current value of the protection component, the protection component cuts off the path of the charge and discharge current to achieve the function of overcurrent protection.

The protection element of the present invention includes a first overcurrent protection component, a switching component, and a heat generating component. The first overcurrent protection component is configured to provide a first bidirectional current path between the first input and output of the protection component and the second input and output. When the current between the first input and output terminals and the second input and output terminals is abnormal, the first overcurrent protection component turns off the first bidirectional current Path for overcurrent protection. The switching element is coupled between the first input and output ends of the protection element and the third input and output end, and the initial state of the switching element is an open state. A first end of the heat generating component is coupled to one end of the first overcurrent protection component. When the heat generating component generates heat, the first overcurrent protection component breaks the first bidirectional current path in response to the heat generated by the heat generating component, and the switching component switches to the short circuit state in response to the heat generated by the heat generating component. A second bidirectional current path is provided between the first input and output terminals and the third input and output terminals.

In an embodiment of the invention, the first end of the heat generating component is further coupled to the first input output or the second input and output end, and the second end of the heat generating component is coupled to the output end of the protection component .

In an embodiment of the invention, the protection element further includes an insulating substrate, a first terminal electrode, a second terminal electrode, a third terminal electrode, a fourth terminal electrode, and an insulating layer. The heat generating component is disposed on the first surface of the insulating substrate. The first end electrode is disposed on the first surface of the insulating substrate to serve as a first input and output end. The second end electrode is disposed on the first surface of the insulating substrate to serve as a second input and output end. The third end electrode is disposed on the first surface of the insulating substrate to serve as a third input and output end. The fourth end electrode is disposed on the insulating substrate to serve as an output end. The insulating layer is disposed between the heat generating component, the first end electrode, the second end electrode, and the third end electrode. The first overcurrent protection component is a first fusible conductor disposed on the first end electrode and the second end electrode, and two ends of the first fusible conductor are electrically connected to the first end electrode and the second end electrode, respectively. When the heat generating component generates heat, the first fusible conductor is blown, causing the first terminal electrode to be electrically insulated from the second terminal electrode, and causing the first terminal electrode to be electrically connected to the third terminal electrode.

In an embodiment of the invention, the protection element further includes an insulating substrate, a first end electrode, a second end electrode, a third end electrode, and a fourth end electrode. The insulating substrate includes a first surface and a second surface, wherein the first surface and the second surface oppose each other. The first end electrode is disposed on the first surface of the insulating substrate to serve as a first input and output end. The second end electrode is disposed on the first surface of the insulating substrate to serve as a second input and output end. The third end electrode is disposed on the first surface of the insulating substrate to serve as a third input and output end. The fourth end electrode is disposed on the insulating substrate to serve as an output end. The heat generating component is disposed on the second surface of the insulating substrate and electrically connected to the first terminal electrode or the second terminal electrode through the conductive electrode. The first overcurrent protection component is a first fusible conductor disposed on the first end electrode and the second end electrode, and two ends of the first fusible conductor are electrically connected to the first end electrode and the second end electrode, respectively. When the heat generating component generates heat, the first fusible conductor is blown, causing the first terminal electrode to be electrically insulated from the second terminal electrode, and causing the first terminal electrode to be electrically connected to the third terminal electrode.

In an embodiment of the invention, the protection element further includes a plurality of heat collecting portions. The heat collecting portions are disposed inside the insulating substrate, and are electrically or thermally connected to the first end electrode, the second end electrode, and the third end electrode, respectively. The heat collecting portions extend further to the second surface and are electrically insulated from the heat generating component to conduct heat generated by the heat generating component to the first end electrode, the second end electrode, and the third end electrode.

In an embodiment of the invention, the protection element further includes an insulating substrate, a first end electrode, a second end electrode, a third end electrode, and a fourth end electrode. The first end electrode is disposed on the first surface of the insulating substrate to serve as a first input and output end. The second end electrode is disposed on the first surface of the insulating substrate for use as the second Input and output. The third end electrode is disposed on the first surface of the insulating substrate to serve as a third input and output end. The fourth end electrode is disposed on the insulating substrate to serve as an output end. The heat generating component is disposed in the insulating substrate, electrically connected to the first terminal electrode or the second terminal electrode through the conductive electrode in the insulating substrate, and is electrically connected to the fourth terminal electrode through the internal electrode in the insulating substrate. The first overcurrent protection component is a first fusible conductor disposed on the first end electrode and the second end electrode, and two ends of the first fusible conductor are electrically connected to the first end electrode and the second end electrode, respectively. When the heat generating component generates heat, the first fusible conductor is blown, causing the first terminal electrode to be electrically insulated from the second terminal electrode, and causing the first terminal electrode to be electrically connected to the third terminal electrode.

In an embodiment of the invention, the switching element includes a second fusible conductor, and the second fusible conductor is disposed on one of the first end electrode and the third end electrode. When the heat generating component generates heat, the second fusible conductor is melted to cause the first terminal electrode to be electrically connected to the third terminal electrode.

In an embodiment of the invention, the protection element further includes a second overcurrent protection component coupled between the first end and the second input end of the heat generating component, when the heat generating component generates heat The second overcurrent protection component disconnects the current path of the second overcurrent protection component or the heat generating component in response to heat generated by the heat generating component, and the heat generating component stops heating.

In an embodiment of the invention, the protection element further includes a second overcurrent protection component coupled to one end of the first overcurrent protection component and the first component of the heat generating component Between one end, or the second overcurrent protection component is coupled between the second end of the heat generating component and the output of the protection component, when the heat When the component generates heat, the second overcurrent protection component reacts with heat generated by the heat generating component to disconnect the current path of the second overcurrent protection component or the heat generating component, causing the heat generating component to stop generating heat.

In an embodiment of the invention, the protection element further includes an insulating substrate, a first end electrode, a second end electrode, a third end electrode, a fourth end electrode, and a first inner electrode. An insulating substrate, wherein the heat generating component is disposed in the insulating substrate or on the first surface of the insulating substrate or on the second surface of the insulating substrate. The first end electrode is disposed on the first surface of the insulating substrate to serve as the first input and output end. The second end electrode is disposed on the first surface of the insulating substrate to serve as the second input and output end. The third end electrode is disposed on the first surface of the insulating substrate to serve as the third input and output end. The fourth end electrode is disposed on the insulating substrate to serve as the output end. The first internal electrode is disposed on the insulating substrate or in the insulating substrate and electrically connected to the first end of the heat generating component. The second end of the heat generating component is electrically connected to the fourth terminal electrode or electrically connected to the fourth terminal electrode through a second internal electrode in the insulating substrate. The first overcurrent protection component and the second overcurrent protection component are first fusible conductors, and the first fusible conductor is disposed on the first end electrode, the second end electrode, and the first internal electrode. The first fusible conductor is electrically connected to the first end electrode, the second end electrode and the first inner electrode, respectively, when the heat generating component generates heat, the first fusible conductor is blown, so that the first The terminal electrode is electrically insulated from the second terminal electrode, and the first terminal electrode is electrically connected to the third terminal electrode.

In an embodiment of the invention, the protection element further includes an insulating substrate, a first end electrode, a second end electrode, a third end electrode, a fourth end electrode, a first inner electrode, and a second inner electrode. An insulating substrate, wherein the heat generating component is disposed in the insulating substrate or The first surface of the insulating substrate or the second surface of the insulating substrate. The first end electrode is disposed on the first surface of the insulating substrate to serve as the first input and output end. The second end electrode is disposed on the first surface of the insulating substrate to serve as the second input and output end. The third end electrode is disposed on the first surface of the insulating substrate to serve as the third input and output end. The fourth end electrode is disposed on the insulating substrate to serve as the output end. The first internal electrode is disposed on the insulating substrate or in the insulating substrate and electrically connected to the first end of the heat generating component. The second internal electrode is disposed on the insulating substrate or in the insulating substrate and electrically connected to the second end of the heat generating component. The first overcurrent protection component is a first fusible conductor, and the first fusible conductor is disposed on the first end electrode and the second end electrode, and the first fusible conductor is electrically connected to the first a terminal electrode and the second terminal electrode. Wherein the second overcurrent protection component is a fourth fusible conductor, the fourth fusible conductor is disposed on the fourth end electrode and the second inner electrode, and the fourth fusible conductor is electrically connected to the fourth end respectively An electrode and the second inner electrode. The second end of the heat generating component is electrically connected to the fourth fusible conductor through a second internal electrode, and the first end of the heat generating component is electrically connected to the first fusible conductor through the first internal electrode. When the heat generating component generates heat, the first fusible conductor is blown, so that the first terminal electrode is electrically insulated from the second terminal electrode, and the first terminal electrode is electrically connected to the third terminal electrode. The fourth fusible conductor is also fused in response to heat generated by the heat generating component.

In an embodiment of the invention, the switching element includes a second fusible conductor, and the second fusible conductor is disposed on one of the first end electrode and the third end electrode, when the heat When the component is heated, the second fusible conductor is melted to electrically connect the first terminal electrode to the third terminal electrode.

In an embodiment of the invention, the protection element has a resistance of the second overcurrent protection component that is less than a resistance of the first overcurrent protection component, or wherein a maximum current rating or power of the second overcurrent protection component is greater than The highest rated current or power of the first overcurrent protection component.

In an embodiment of the invention, the protection element further includes an insulating substrate, a first end electrode, a second end electrode, a third end electrode, and a fourth end electrode. Wherein the heat generating component is disposed in the insulating substrate or on the first surface of the insulating substrate or on the second surface of the insulating substrate. The first end electrode is disposed on the first surface of the insulating substrate to serve as a first input and output end. The second end electrode is disposed on the first surface of the insulating substrate to serve as a second input and output end. The third end electrode is disposed on the first surface of the insulating substrate to serve as a third input and output end. The fourth end electrode is disposed on the insulating substrate to serve as an output end. The first overcurrent protection component and the second overcurrent protection component are first fusible conductors disposed on the first end electrode and the second end electrode. The two ends of the first fusible conductor are electrically connected to the first end electrode and the second end electrode, respectively, and the first end of the heat generating component is electrically connected between the first end electrode and the second end electrode a first fusible conductor or a portion of the first fusible conductor intermediate end that is biased toward the second end electrode. The switching element includes a second fusible conductor, and the second fusible conductor is disposed on one of the first end electrode and the third end electrode. When the heat generating component generates heat, the first fusible conductor is blown, and the second fusible conductor is melted to electrically connect the first terminal electrode to the third terminal electrode.

The secondary battery pack of the present invention includes a plurality of battery element groups, a plurality of the above-described protection elements, a plurality of switching circuits, and a detection control circuit. Each of the battery element groups includes at least one chargeable battery element. Such protective components and such battery component groups Serially connected to form a charge and discharge current path. Each of the switching circuits is coupled to an output of one of the protective elements. The detection control circuit is configured to detect the voltage or temperature of the battery component groups, and determine the state of each of the switch circuits according to the detected voltage or temperature. If the voltage or temperature of the battery element group is normal, the switching circuits are switched to the open state. If the voltage or temperature of any of the battery element groups is abnormal, the switching circuit of the battery element group corresponding to the abnormality is switched to the on state, causing the protection element of the battery element group corresponding to the abnormality to be disconnected. A charge and discharge current path between the abnormal battery element groups, and switching the charge and discharge current path to the remaining normal battery element groups in the battery element group. When an overcurrent condition occurs when the charge/discharge current flowing through any of the protective elements exceeds the rated current value, the protection element that has an overcurrent condition turns off the charge and discharge current path.

In an embodiment of the invention, the secondary battery pack further includes a charge and discharge control circuit. The charge and discharge control circuit is configured to determine whether to transmit a charging current from the external device to the battery component group or to transmit a discharge current from the battery component group according to the state of the voltage detected by the detection control circuit and the type of the external device. External device.

The above described features and advantages of the invention will be apparent from the following description.

1‧‧‧Charging device or electronic device

2‧‧‧Charge and discharge control circuit

110, 110a, 110b, 110g‧‧‧ insulating substrate

1101, 1102‧‧‧ secondary batteries

1111‧‧‧Power storage device

End points 1111a, 111c, 2013‧‧‧

1121, 1122‧‧‧Fuse components

1123‧‧‧heater

118a, 118b‧‧‧ Conductive electrodes

121, 121a, 121b, 121g, 122, 122a, 122b, 122g, 123, 123a, 123b, 123g, 124, 124a, 124b, 124g‧‧‧

125, 125g‧‧‧ heat storage electrode

130, 130a, 130b, 16g‧‧‧ solder

140, 140a, 140b, 190g‧‧‧ fluxing materials

151a, 152a, 153a‧‧ ‧ heat collection department

160, 160g‧‧‧ insulation

168, 168a‧‧‧Insulating components

170, 170', 170a, 170b, 170g, 171, 171a, 171b, 171g, 171h, 172, 172a, 172b‧‧‧ fusible conductor

181, 182, 181a, 181b, 182b‧ ‧ internal electrodes

188, 188a, 188b, 188g‧‧‧ heat generating components

2001‧‧‧Protection circuit

2002‧‧‧Battery Pack

2003‧‧‧ battery unit

2012‧‧‧heating body

2016‧‧‧fusible conductor

4a, 4b‧‧‧ battery component group

4-1, 4-2, 4-3, 4-4‧‧‧ battery components

588‧‧‧Secondary battery pack

5a, 5b‧‧‧Detection control circuit

6a, 6b‧‧‧ switch circuit

7, 7a1, 7a2‧‧‧ heat generating components

8, 8a1, 8a2, 8c, 8d, 8e, 8e', 8f, 8f', 2005, 100, 100', 100a, 100b, 100c, 100d, 100e, 100e', 100f, 100f', 100g, 100g1, 100h , 100m, 100n‧‧‧protective components

9, 9_1, 9a1, 9a2‧‧‧Overcurrent protection components

D‧‧‧ gap

D1‧‧‧ aperture

D3‧‧‧Width

I‧‧‧current direction switch

Ic, Id‧‧‧ charge and discharge current path

I/O1, I/O2, I/O4‧‧‧ input and output

N‧‧‧negative

N1‧‧‧

O3‧‧‧ output

P‧‧‧ positive

PTC1, PTC2‧‧‧ positive temperature coefficient components

S, S1, S2‧‧‧ switching components

X-X’, Y-Y’‧‧‧ line

1A and 1B are circuit diagrams illustrating a prior art related secondary battery.

2 is a circuit diagram illustrating a prior art related battery pack.

3A is a circuit diagram of a secondary battery pack according to an embodiment of the present invention.

3B, 3C and 3D are schematic diagrams showing the operation of a secondary battery pack according to an embodiment of the present invention.

4 is a circuit diagram of a secondary battery pack according to another embodiment of the present invention.

FIG. 5 is a circuit diagram of a protection element according to an embodiment of the present invention.

6A is a top plan view of a protection element according to an embodiment of the invention.

Figure 6B is a cross-sectional view of the protection element of Figure 6A taken along line X-X'.

FIG. 6C is a schematic top view of a protection element according to an embodiment of the invention.

Figure 6D is a cross-sectional view of the protective element of Figure 6C taken along line X-X'.

FIG. 6F is a schematic top view of a protection element according to an embodiment of the invention.

6E is a cross-sectional view of a protection element according to an embodiment of the invention.

FIG. 7 is a circuit diagram of another protection element according to an embodiment of the present invention.

FIG. 8 is a top plan view of a protection element according to an embodiment of the present invention.

FIG. 9 is a circuit diagram of still another protection element according to an embodiment of the present invention.

Figure 10 is a top plan view of a protective element in accordance with an embodiment of the present invention.

FIG. 11A is a circuit diagram of another protection element according to an embodiment of the present invention.

FIG. 11B is a top plan view of a protection element according to an embodiment of the invention.

FIG. 11C is a circuit diagram of another protection element according to an embodiment of the present invention.

11D is a top plan view of a protection element according to an embodiment of the invention.

FIG. 12A is a circuit diagram of still another protection element according to an embodiment of the present invention.

FIG. 12B is a schematic top view of a protection element according to an embodiment of the invention.

FIG. 12C is a circuit diagram of still another protection element according to an embodiment of the present invention.

12D is a top plan view of a protection element according to an embodiment of the invention.

In order to further understand the features and technical contents of the present invention, reference should be made to the following related embodiments, which are described in detail below with reference to the accompanying drawings. In addition, wherever possible, the same reference numerals in the drawings

FIG. 3A is a circuit diagram of a secondary battery pack 588 according to an embodiment of the invention. The secondary battery pack 588 includes battery element groups 4a and 4b, detection control circuits 5a and 5b, charge and discharge control circuit 2, switch circuits 6a and 6b, and protection elements 8a1, 8a2. Each of the battery element groups 4a, 4b has two chargeable and dischargeable battery elements (4-1, 4-2, 4-3, 4-4). The detection control circuit 5a, 5b can detect each battery element (4-1, 4-2, 4-3, 4-4) in the battery element group 4a, 4b or a voltage or battery element group of a specific battery element The temperature in 4a, 4b. The charge and discharge control circuit 2 can determine whether to input the charging current or output according to the voltage condition of the battery element groups 4a and 4b measured by the detection control circuits 5a, 5b and whether the external device is the charging device 1 or the electronic device 1. Discharge current. The switch circuits 6a, 6b can determine whether to maintain an off state or switch to an on state according to the voltage or temperature condition measured by the detection control circuits 5a, 5b. When the voltage or temperature is normal, the switch circuits 6a and 6b are maintained in the open state, and if the voltage or temperature is abnormal, the switch circuits 6a and 6b are switched to the on state. When any of the battery element groups 4a or 4b is overcharged or overvoltage or overtemperature, the protection element 8a1 or 8a2 disconnects the abnormal battery element group 4a or 4b, and switches the charge and discharge current paths Ic, Id to other normal. Battery element group 4a or 4b. When the charge and discharge current exceeds the rated current value of the protection element 8a1 or 8a2, the protection element 8a1 or 8a2 cuts off the charge and discharge current paths Ic, Id.

In detail, the protection element 8a1 includes an overcurrent protection element 9a1, a heat generation component 7a1, and a switching element S1. The overcurrent protection element 9a1 is connected in series between the charge and discharge control circuit 2 and the battery element group 4a (i.e., the first bidirectional current path) to provide bidirectional charge and discharge current paths Ic, Id. One end of the heat generating unit 7a1 is connected to one end of the current protection element 9a1, and the other end of the heat generating unit 7a1 is connected to the switch circuit 6a. One end of the switching element S1 is connected to the overcurrent protection element 9a1 and the charge and discharge control circuit 2, and the other end of the switching element S1 is connected to the common terminal of the other protection element 8a2 and the battery element group 4a. The other protective element 8a2 includes an overcurrent protection element 9a2, a heat generating component 7a2, and a switching element S2. The overcurrent protection element 9a2 is connected in series between the battery element groups 4a and 4b to provide a bidirectional charge and discharge current path Ic, Id (i.e., a first bidirectional current path). One end of the heat generating unit 7a2 is connected to one end of the overcurrent protection element 9a2 and the battery element group 4b, and the other end of the heat generating unit 7a2 is connected to the switch circuit 6b. One end of the switching element S2 is connected to one end of the overcurrent protection element 9a2 and the battery element group 4a, and the other end of the switching element S2 is connected to the switching circuit 6a and the charge and discharge control circuit 2.

The protection operation for the secondary battery pack 588 will be described below. In detail, FIG. 3A is a circuit diagram of the secondary battery pack 588 in a normal state. When both the charging current and the discharging current are normal, and the voltage and temperature of the two battery element groups 4a and 4b are also normal, the two protective elements 8a1 8a2 does not operate, and both switching circuits 6a, 6b are maintained in an off state, and the switching elements S1, S2 of the two protection elements 8a1, 8a2 are also maintained in an off state. When the external device is the charging device 1, and the voltage of the battery element groups 4a, 4b is lower than a certain value, the charge and discharge control circuit 2 switches the current direction switch I to input the charging current. The charging current charges the two battery element groups 4a and 4b along the charging current path Ic as shown in Fig. 3A. When the voltage of the battery element groups 4a and 4b is higher than a certain value, the charge and discharge control circuit 2 turns off the current direction switch I, and stops inputting the charging current. If externally installed When the electronic device 1 is set and the voltage measured by the detection control circuits 5a and 5b is within a certain value range, the charge and discharge control circuit 2 switches the current direction switch I to output a discharge current to discharge the electronic device 1. The discharge current discharges the electronic device 1 along the discharge current path Id as shown in FIG. 3A. When the voltage of the battery element groups 4a and 4b is lower than a certain value, the charge and discharge control circuit 2 turns off the current direction switch I, and stops outputting the discharge current.

FIG. 3B is a circuit diagram when an abnormality occurs in the battery element group 4a, such as overcharge or overvoltage or overtemperature. Assuming that the external device is the charging device 1 at this time, when the detection control circuit 5a detects that the voltage or temperature of the battery element group 4a exceeds a normal value, the detection control circuit 5a transmits a signal to the switching circuit 6a to make the switching circuit 6a switches to the on state. At this time, the current I _7a1 flows through the overheat generating unit 7a1, causing the heat generating unit 7a1 to generate heat to cut off the charging current path Ic of the overcurrent protection element 9a1, and to switch the switching element S1 from the open or open state to the on or short state. (ie, the second bidirectional current path) to switch the charge and discharge current paths Ic, Id to the protection element 8a2 without flowing through the battery element group 4a. It should be particularly noted that the protective element 8a1 of the present invention has an advantage that when an overvoltage or overcharge occurs in the battery element group 4a, the charging current path Ic of the overcurrent protection element 9a1 is cut off, at this time, the battery element group 4a Still in an overvoltage or overcharge state, the protection element 8a1 of the present invention can still provide a discharge path for the current of the battery element group 4a to flow through the heat generating component 7a1 until the battery element group 4a is de-energized or Overcharged state. This not only ensures that the battery element group 4a does not overcharge, but also allows the normal battery element group 4b to continue to provide the function of charging and discharging. Of course, if all of the battery element groups 4a, 4b exhibit an abnormal phenomenon (such as overcharge or overtemperature), the secondary battery pack 588 loses the function of providing power or charging and discharging.

FIG. 3C is a circuit diagram when an abnormality occurs in the battery element group 4b, such as overcharge or overvoltage or overtemperature. Assuming that the external device is the charging device 1 at this time, when the detection control circuit 5b detects that the voltage or temperature of the battery element group 4b exceeds a normal value, the detection control circuit 5b transmits a signal to the switch circuit 6b to switch the circuit 6b. Switched to the on state. At this time, the current I _7a2 flows through the overheat generating unit 7a2, causing the heat generating unit 7a2 to generate heat to cut off the charging current path Ic of the overcurrent protecting element 9a2, and to switch the switching element S2 from the open or open state to the on or short state. The charge and discharge current paths Ic, Id are switched to the charge and discharge control circuit 2 without flowing through the battery element group 4b. It should be particularly noted that the protective element 8a2 of the present invention has an advantage that when an overvoltage or overcharge occurs in the battery element group 4b, the charging current path Ic of the overcurrent protection element 9a2 is cut off, at which time the battery element group 4b Still in an overvoltage or overcharge state, the protection element 8a2 of the present invention can still provide a discharge path for the current of the battery element group 4b to flow through the heat generating component 7a2 until the battery element group 4b is de-energized. Or overcharged state. This not only ensures that the battery element group 4b does not always maintain an overcharge or overvoltage, but also allows the normal battery element group 4a to continue to provide the function of charging and discharging or to maintain the function of the secondary battery pack 588 to continuously supply power. Of course, if all of the battery element groups 4a, 4b exhibit an abnormal phenomenon (such as overcharge or overtemperature), the secondary battery pack 588 loses the function of providing power or charging and discharging.

FIG. 3D is a circuit diagram when the current value of the charging current is higher than the rated current value of the overcurrent protection element 9a1, or the discharge current value is higher than the rated current value of the overcurrent protection element 9a1. The cause of this abnormality is as follows: a short circuit between the positive electrode P and the negative electrode N or an abnormal current output from the charging device 1. At this time, the voltage or temperature of the battery element groups 4a, 4b are in the normal range, so the detection control circuits 5a, 5b do not send signals to the switch circuits 6a, 6b, so the switch circuits 6a, 6b are maintained in an off state. Therefore, no current can pass through the heat generating units 7a1, 7a2, so that the heat generating units 7a1, 7a2 do not generate heat, and at this time, the switching elements S1, S2 are maintained in an off state. However, any of the overcurrent protection elements 9a1, 9a2 may have a higher current value due to the charging current than the overcurrent The rated current value or the discharge current value of the protection element 9a1 or 9a2 is higher than the rated current value of the overcurrent protection element 9a1 or 9a2, and the charge and discharge current paths Ic, Id are turned off. As shown in FIG. 3D, the charge and discharge current paths Ic, Id of the overcurrent protection element 9a1 are turned off, so that the battery element groups 4a, 4b cannot be charged or discharged, and thus the battery element groups 4a, 4b are not charged and discharged by a large amount. The current is charged and discharged to cause damage or danger, so that the function of overcurrent protection and the safety of protecting the secondary battery pack 588 can be achieved.

In the embodiment shown in FIG. 3A, although the safety of the secondary battery pack 588 can be protected, the short circuit between the positive electrode P and the negative electrode N for one unknown reason or the abnormal current of the charging device 1 is output. use. 4 is a circuit diagram of a secondary battery pack 588a according to another embodiment of the present invention. The circuit of the secondary battery pack 588a of the present embodiment is similar to the circuit of the secondary battery pack 588 illustrated in FIG. 3A. The difference is that the circuit of the secondary battery pack 588a of the present embodiment further includes two positive temperature coefficient elements PTC1 and PTC2.

In detail, the positive temperature coefficient element PTC1 is connected in series to the charge and discharge current paths Ic, Id between the charge control circuit 2 and the protection element 8a1. The other positive temperature coefficient element PTC2 is connected in series to the charge and discharge current paths Ic, Id between the battery element group 4a and the protection element 8a2. The rated current values of the overcurrent protection elements 9a1, 9a2 in the protection elements 8a1, 8a2 can be selected or designed according to requirements. Preferably, the rated current value or rated power ratio of the overcurrent protection elements 9a1, 9a2 is positive temperature coefficient element PTC1. PTC2 has a high rated current or rated power. The advantage of this circuit design is that when the charge or discharge power or voltage or current is slightly abnormal, if the current value of the charging current is higher than the rated current value of the positive temperature coefficient components PTC1, PTC2, or the discharge current value When the rated current value of the positive temperature coefficient elements PTC1 and PTC2 is higher, any one of the positive temperature coefficient elements PTC1 and PTC2 will operate, and the positive temperature coefficient element PTC1 or the positive temperature coefficient element The PTC2 will rise from a low resistance value to a high resistance value in a very short period of time to limit the current value of charge and discharge to be lower than the rated current value or rated power of the overcurrent protection elements 9a1, 9a2, thus protecting the secondary battery pack 588a. Security. When an unexplained short circuit between the positive electrode P and the negative electrode N or the abnormal current of the charging device 1 is released, the positive temperature coefficient element PTC1 or PTC2 is restored from the high resistance value to the low resistance value in a very short time. And the secondary battery pack 588a can continue to provide a function of charging and discharging. In addition, when the power or voltage or current of the charge and discharge is severely abnormal, for example, the power value of the charge and discharge of the secondary battery pack 588a or the voltage value of the charge and discharge or the current value of the charge and discharge exceeds the positive temperature coefficient element PTC1. The rated specification of the PTC2, any one of the overcurrent protection elements 9a1, 9a2 will operate faster than the positive temperature coefficient elements PTC1, PTC2 to cut off the charge and discharge current paths Ic, Id, and the charge and discharge current paths Ic, Id will not Recovery, this ensures absolute safety of the secondary battery pack 588a.

FIG. 5 is a circuit diagram of a protection element 8 according to an embodiment of the present invention. The protection element 8 of the present embodiment includes an input/output terminal I/O1, I/O2, I/O4, an output terminal O3, an overcurrent protection component 9, a heat generating component 7, and a switching element S. Two ends of the overcurrent protection component 9 are respectively connected to one input/output terminal I/O1 (or first input and output terminal) and another input/output terminal I/O2 (or second input and output terminal) for providing bidirectional Current paths Ic and Id. One end of the heat generating component 7 is connected to one end of the overcurrent protection element 9 and the input/output terminal I/O2, and the other end of the heat generating component 7 is connected to the output terminal O3. One end of the switching element S is connected to one end of the overcurrent protection element 9 and the input/output terminal I/O1, and the other end of the switching element S is connected to the input/output terminal I/O4 (or the third input terminal). The initial state of the switching element S is maintained in an off state or an off state.

In detail, the resistance value of the heat generating component 7 is greater than the resistance value of the overcurrent protection component 9, and the initial state of the switching element S is maintained in an open or open state, so unless overpowered The current path of the flow protection element 9 is cut off, otherwise the current between the input/output terminal I/O1 and the input/output terminal I/O2 does not flow through the heat generating component 7 or only a small current flows through the heat generating component 7 It is of course also possible to control whether or not current flows through the heat generating unit 7 by the switching circuit 6a or 6b, like the circuit in the secondary battery pack 588 of the embodiment shown in Fig. 3A.

In the protective element 8 of the embodiment shown in FIG. 5 of the present invention, when a current flows through the heat generating unit 7, the heat generating unit 7 generates heat to cut off the current path of the overcurrent protecting member 9, and the switching element is turned on. S switches to a state of on or on, providing a second bidirectional current path between the input and output terminals I/O1 and the input and output terminals I/O4. Once the switching element S is switched to the on or on state, it does not change. In addition, when the current flowing through the current protection element 9 is greater than the rated current value or the rated power value of the overcurrent protection element 9, the overcurrent protection element 9 also turns off the current path of the overcurrent protection element 9 to achieve overcurrent protection. Features.

FIG. 6A is a top plan view of a protection element 100 according to an embodiment of the invention. Figure 6B is a cross-sectional view of the protection element 100 of Figure 6A taken along line X-X'. The protection element 100 of the present embodiment includes an insulating substrate 110, four terminal electrodes 121, 122, 123, 124, a first fusible conductor 170, a heat generating component 188, an insulating layer 160, and a second fusible conductor 171. The first fusible conductor 170 is disposed on the (first) surface of the insulating substrate 110. The first fusible conductor 170 is disposed on the terminal electrodes 121, 122. Both ends of the first fusible conductor 170 are electrically connected to the terminal electrode 121 on which the second fusible conductor 171 is disposed, and the other end is electrically connected to the terminal electrode 122. The first fusible conductor 170 can provide a bidirectional current path. The heat generating assembly 188 is disposed on the (first) surface of the insulating substrate 110. One end of the heat generating component 188 is electrically connected to the first fusible conductor 170 through the inner electrode 181 and the terminal electrode 122, and the other end of the heat generating component 188 is electrically connected to the terminal electrode 123. The insulating layer 160 is disposed between the heat generating component 188 and the terminal electrodes 121, 122, 124. Second fusible conductor 171 It is disposed on the terminal electrode 121. When the heat generating component 188 generates heat, the first fusible conductor 170 is fused, and the second fusible conductor 171 is melted and electrically connected to the terminal electrode 124 where the fusible conductor is not disposed.

In detail, the equivalent circuit diagram of the protection element 100 of the present embodiment is similar to the circuit diagram of the protection element 8 illustrated in FIG. The terminal electrode 121 of the present embodiment is equivalent to the input/output terminal I/O1 of the protection element 8, the terminal electrode 122 is equivalent to the input and output terminal I/O2 of the protection component 8, and the terminal electrode 124 is equivalent to the input and output terminal I/ of the protection component 8. O4, the terminal electrode 123 is equivalent to the output terminal O3 of the protection element 8, the first fusible conductor 170 is equivalent to the overcurrent protection element 9 of the protection element 8, and the second fusible conductor 171 is equivalent to the switching element S of the protection element 8, heat The generating assembly 188 is equivalent to the heat generating assembly 7 of the protective element 8. The description of the related protection action in this embodiment is similar to the description of the protection element 8 in the embodiment of FIG. 5, please refer to it yourself, and details are not described herein again.

It should be particularly noted that the first fusible conductor 170 may be blown due to the current flowing through the first fusible conductor 170 exceeding the rated current or rated power of the first fusible conductor 170, or may be blown by the heat generated by the heat generating component 188. The area or volume or thickness of the terminal electrode 121 overlapping the second fusible conductor 171 is smaller than the area or volume or thickness of the second fusible conductor 171, and thus the second fusible conductor that melts and liquefies when the heat generating component 188 generates heat. 171, will overflow to the adjacent terminal electrode 124, causing the terminal electrodes 121, 124 to be shorted or electrically connected. In addition, the first fusible conductor 170 may electrically connect the terminal electrodes 121, 122 via the solder 130, and the second fusible conductor 171 may electrically connect the terminal electrode 121 via the solder 130.

In another variant embodiment, the protection element 100 of the present embodiment further comprises a third fusible conductor 172. The third fusible conductor 172 is disposed on the terminal electrode 124 and electrically connected to the terminal electrode 124. It should be noted that the area of the terminal electrode 124 of the portion overlapping the third fusible conductor 172 or The volume or thickness is smaller than the area or volume or thickness of the third fusible conductor 172, so that the second fusible conductor 171 and the third fusible conductor 172 that are melted and liquefied when the heat generating component 188 generates heat may overflow to the adjacent terminal electrode. 124, 121, causing the terminal electrodes 121, 124 to be short-circuited or electrically connected. In addition, the third fusible conductor 172 can be electrically connected to the terminal electrode 124 via the solder 130.

In another variant embodiment, the protective element 100 of the present embodiment further includes a fluxing material 140. The fluxing material 140 is disposed between the second fusible conductor 171, the terminal electrodes 121 and 124 where the third fusible conductor 172 is located, and all of the fusible conductors 170, 171, 172. (Of course, it is also possible to arrange between the terminal electrodes 121 and 124 and the terminal electrode 121, the terminal electrode 124, the fusible conductor 170, the fusible conductor 171, the fusible conductor 172, or a combination thereof).

In another variant embodiment, the protective element 100 of the present embodiment further includes an insulating member 168. The insulating member 168 is disposed at the edge of the second fusible conductor 171 or the third fusible conductor 172 or the second fusible conductor 171 and the third fusible conductor 172, and may limit the melted second fusible conductor 171 or the third The direction in which the fuse conductor 172 or the second fusible conductor 171 overflows with the third fusible conductor 172 causes the terminal electrodes 121, 124 to be quickly shorted or electrically connected.

For another variant embodiment, please refer to the protective element 100' shown in Figure 6F. The architecture of the protection element 100' is similar to the architecture of the protection element 100 shown in Figure 6A. The only difference is that the first fusible conductor 170 and the second fusible conductor 171 of the protection element 100 shown in FIG. 6A can be combined and simplified into the first fusible conductor of the protection element 100' shown in FIG. 6F. 170'. In detail, the first fusible conductor 170' of Fig. 6F is disposed on the terminal electrodes 121, 122. Both ends of the first fusible conductor 170' are electrically connected to the terminal electrode 121 and adjacent to the terminal electrode 124, and the other end is electrically connected to the terminal electrode 122. As such, when the heat generating component 188 of the protective component 100' generates heat, the first fusible conductor 170' will be blown to electrically insulate the terminal electrode 121 from the terminal electrode 122 (i.e., the terminal electrode 121). The bidirectional current path between the terminal electrode 122 and the terminal electrode 122 will be broken, and the partially melted first fusible conductor 170' can flow into the gap between the terminal electrode 121 and the terminal electrode 124 to cause the terminal electrode 121 to be electrically connected to Terminal electrode 124.

FIG. 6C is a schematic top view of a protection element 100a according to an embodiment of the invention. Figure 6D is a cross-sectional view of the protective element 100a of Figure 6C taken along line X-X'. The protective element 100a of the present embodiment includes an insulating substrate 110a, four terminal electrodes 121a, 122a, 123a, 124a, a first fusible conductor 170a, a second fusible conductor 171a, and a heat generating component 188a. The insulating substrate 110a includes a first surface and a second surface, wherein the first surface and the second surface oppose each other. The terminal electrodes 121a, 122a, 123a, 124a are disposed on the first surface of the insulating substrate 110a. The first fusible conductor 170a is disposed on the terminal electrodes 121a, 122a. Both ends of the first fusible conductor 170a are electrically connected to the terminal electrode 121a of the second fusible conductor 171a, and the other end is electrically connected to the other end electrode 122a. The first fusible conductor 170a can provide a bidirectional current path. The heat generating component 188a is disposed on the second surface of the insulating substrate 110a. One end of the heat generating component 188a is electrically connected to the first fusible conductor 170a through the conductive electrode 118a, and the other end of the heat generating component 188a is electrically connected to the terminal electrode 123a. When the heat generating component 188a generates heat, the first fusible conductor 170a is blown, and the second fusible conductor 171a is melted and electrically connected to the terminal electrode 124a where the fusible conductor is not disposed. It should be particularly noted that one end of the heat generating component 188a can electrically connect the first fusible conductor 170a via the inner electrode 181a, the conductive electrode 118a, and the terminal electrode 122a. Other descriptions of the protective action, the third fusible conductor 172a, the solder 130a, the fluxing material 140a, the insulating member 168a, and other related descriptions are similar to those described above for the protective element 100 of FIG. 6A, please refer to it here. No longer.

Another modified embodiment, the terminal electrode of the protection element 100a of the present embodiment The 121a, 122a, and 124a respectively include heat collecting portions 152a, 151a, and 153a. The heat collecting portions 151a, 152a, and 153a are disposed in the insulating substrate 110a, and are electrically or thermally connected to the second terminal electrode 122a, the first terminal electrode 121a, and the third terminal electrode 124a, respectively. The heat collecting portion 152a of the first end electrode 121a, the heat collecting portion 151a of the second end electrode 122a, and the heat collecting portion 153a of the third end electrode 124a may extend to be closest to the heat generating component 188a and be capable of being electrically connected to the heat generating component 188a. Sexual insulation has the best heat transfer position. The heat collecting portions 151a, 152a, and 153a have the advantages of accelerating the heat conduction of the heat generating assembly 188a, causing the terminal electrodes 121a, 122a, and 124a to fuse or melt the fusible conductors 170a, 171a, 172a, the heat collecting portions 151a, 152a, and the like more quickly. The material of 153a may include one of metal, a material having a high thermal conductivity, or a combination thereof.

In another modified embodiment, the first fusible conductor 170a of the protection element 100a shown in FIG. 6C and the second fusible conductor 171a can be combined and simplified to be similar to the first one of the protection element 100' shown in FIG. 6F. The detailed configuration and operation of the fuse conductor 170' can be referred to the related description of FIG. 6F, and will not be described herein.

FIG. 6E is a cross-sectional view of a protection element 100b according to an embodiment of the invention. The protective element 100b of the present embodiment includes an insulating substrate 110b, four terminal electrodes 121b, 122b, 123b, 124b, a first fusible conductor 170b, a second fusible conductor 171b, and a heat generating component 188b. The terminal electrodes 121b, 122b, 123b, and 124b are disposed on the (first) surface of the insulating substrate 110b. The first fusible conductor 170b is disposed on the terminal electrodes 121b, 122b. Both ends of the first fusible conductor 170b are electrically connected to the terminal electrode 121b of the second fusible conductor 171b, and the other end is electrically connected to the other end electrode 122b. The first fusible conductor 170b can provide a bidirectional current path. The heat generating component 188b is disposed in the insulating substrate 110b. One end of the heat generating component 188b is electrically connected to the first fusible conductor 170b, and the other end of the heat generating component 188b is electrically connected to the terminal electrode. 123b. When the heat generating component 188b generates heat, the first fusible conductor 170b is blown, and the second fusible conductor 171b is melted so that the terminal electrode 121b is electrically connected to the terminal electrode 124b where the fusible conductor is not disposed.

It should be particularly noted that one end of the heat generating component 188b can be electrically connected to the first fusible conductor 170b via the inner electrode 181b, the conducting electrode 118b and the terminal electrode 122b, and the other end of the heat generating component 188b can be electrically connected to the terminal electrode via the inner electrode 182b. 123b. Other descriptions of the protective action, the third fusible conductor 172b, the solder 130b, the fluxing material 140b, the insulating member (not shown), and other related descriptions are similar to those described in the protective element 100 of FIG. 6A, please See, no more details here.

In another variant embodiment, the first fusible conductor 170b of the protective element 100b shown in FIG. 6E can be combined and simplistic to be similar to the first fusible conductor 171b as shown in FIG. 6F. The detailed configuration and operation of the fuse conductor 170' can be referred to the related description of FIG. 6F, and will not be described herein.

FIG. 7 is a circuit diagram of another protection element 8c according to an embodiment of the present invention. The circuit of the protection element 8c shown in FIG. 7 is similar to the circuit of the protection element 8 shown in FIG. 5, and the overcurrent protection element 9 and the input/output terminal I are connected to one end of the heat generating component 7 of the protection element 8 of FIG. One end of the /O2 common connection, one end of the heat generating component 7 of the protective element 8c of Fig. 7 is connected to one end of the overcurrent protection element 9 and the input/output terminal I/O1. The description of the related protection action of the embodiment of FIG. 7 is similar to the description of the protection element 8 of the embodiment of FIG. 5, please refer to it yourself, and details are not described herein again. In addition, the secondary battery pack 588 of FIG. 3A and the protective elements 8a1, 8a2 of the secondary battery pack 588a of FIG. 4 may be replaced with the protective member 8c shown in FIG.

FIG. 8 is a top plan view of a protection element 100c according to an embodiment of the present invention. this The protective element 100c of the embodiment includes an insulating substrate 110, four terminal electrodes 121, 122, 123, 124, a first fusible conductor 170, a heat generating component 188, an insulating layer 160, and a second fusible conductor 171. The terminal electrodes 121, 122, 123, 124 are disposed on the (first) surface of the insulating substrate 110. The first fusible conductor 170 is disposed on the terminal electrodes 121, 122. Both ends of the first fusible conductor 170 are electrically connected to the terminal electrode 121 on which the second fusible conductor 171 is disposed, and the other end is electrically connected to the terminal electrode 122. The first fusible conductor 170 can provide a bidirectional current path. The heat generating assembly 188 is disposed on the (first) surface of the insulating substrate 110. One end of the heat generating component 188 is electrically connected to the first fusible conductor 170 through the inner electrode 181 and the terminal electrode 121, and the other end of the heat generating component 188 is electrically connected to the terminal electrode 123. The insulating layer 160 is disposed between the heat generating component 188 and the terminal electrodes 121, 122, 124. The second fusible conductor 171 is disposed on the terminal electrode 121. When the heat generating component 188 generates heat, the first fusible conductor 170 is fused, and the second fusible conductor 171 is melted and electrically connected to the terminal electrode 124 where the fusible conductor is not disposed.

The equivalent circuit diagram of the protection element 100c of the present embodiment is similar to the circuit diagram of the protection element 8c shown in FIG. 7. The terminal electrode 121 of the present embodiment is equivalent to the input/output terminal I/O1 of the protection element 8c, and the terminal electrode 122 is equivalently protected. The input/output terminal I/O2 of the component 8c, the terminal electrode 124 is equivalent to the input/output terminal I/O4 of the protection component 8c, the terminal electrode 123 is equivalent to the output terminal O3 of the protection component 8c, and the first fusible conductor 170 is equivalent to the protection component 8c. The overcurrent protection element 9, the second fusible conductor 171 is equivalent to the switching element S of the protection element 8c, and the heat generating component 188 is equivalent to the heat generating component 7 of the protection element 8c. The description of the related protection action in this embodiment is similar to the description of the protection element 8c in the embodiment of FIG. 7. Please refer to it here, and no further details are provided herein.

In another modified embodiment, the first fusible conductor 170 of the protection element 100c shown in FIG. 8 can be combined and simplified to be similar to the protection shown in FIG. 6F. The detailed configuration and operation of the first fusible conductor 170' of the component 100' can be referred to the related description of FIG. 6F, and will not be described herein.

FIG. 9 is a circuit diagram of still another protection element 8d according to an embodiment of the present invention. The circuit of the protection element 8d shown in FIG. 9 is similar to the circuit of the protection element 8 shown in FIG. 5, and the difference is that the protection element 8d shown in FIG. 9 further includes another overcurrent protection element 9_1, overcurrent protection. One end of the component 9_1 is coupled to one end of the heat generating component 7 and the overcurrent protection component 9, and the other end of the overcurrent protection component 9_1 is coupled to the input/output terminal I/O2 to input and output I/O1 and A bidirectional current path Ic, Id is provided between the input and output terminals I/O2. The resistance of the overcurrent protection element 9_1 is smaller than the resistance of the overcurrent protection element 9, or the highest rated current of the overcurrent protection element 9_1 is greater than the highest rated current of the overcurrent protection element 9, or the highest rated power of the overcurrent protection element 9_1 is greater than the overcurrent The highest rated power of the protection component 9, so when an abnormal current (or a large current) occurs between the input/output terminal I/O1 and the input/output terminal I/O2, the overcurrent protection component 9 is fixedly disconnected preferentially at the input and output terminals. The bidirectional current path Ic, Id between I/O1 and I/O2, the current path of the overcurrent protection component 9_1 itself remains normal, that is, I/O1 at the input and output terminals and I/O2 at the input and output terminals. Between the functions or functions of overcurrent protection provided by the overcurrent protection component 9 is fixed.

The description of the related protection action of the embodiment of FIG. 9 is similar to the description of the protection element 8 of the embodiment of FIG. 5. Please refer to it for details, and no further details are provided herein. It should be specially noted that when a current flows through the heat generating component 7, the heat generating component 7 generates heat to cut off the current path of the overcurrent protecting component 9, 9_1 (or the first input/output terminal I/O1 and the second Input current path between the output I/O2), when the current path of the overcurrent protection element 9, 9_1 is cut off, the current flowing through the heat generating component 7 is also cut off (no current), and the heat generating component 7 is stopped. Heating, that is to say the technical characteristics of the overcurrent protection element 9_1 The problem is that when the heat generating component is heated for a period of time, the overcurrent protecting component 9_1 is responsible for breaking the current flowing through the heat generating component 7, and causing the generating component 7 to stop continuing to generate heat. In addition, the secondary battery pack 588 of FIG. 3A and the protective elements 8a1, 8a2 of the secondary battery pack 588a of FIG. 4 may be replaced with the protective member 8d shown in FIG.

FIG. 10 is a top plan view of a protection element 100d according to an embodiment of the present invention. The protection element 100d of the present embodiment includes: an insulating substrate 110, four terminal electrodes 121, 122, 123, 124, a thermal storage electrode 125, a first fusible conductor 170, a heat generating component 188, an insulating layer 160, and a second fusible conductor. 171. The terminal electrodes 121, 122, 123, and 124 and the heat storage electrode 125 are disposed on the (first) surface of the insulating substrate 110. The first fusible conductor 170 is disposed on the terminal electrodes 121, 122 and the heat storage electrode 125. Both ends of the first fusible conductor 170 are electrically connected to the terminal electrode 121 on which the second fusible conductor 171 is disposed, and the other end is electrically connected to the terminal electrode 122. The first fusible conductor 170 can provide a bidirectional current path. The heat generating assembly 188 is disposed on the (first) surface of the insulating substrate 110. One end of the heat generating component 188 is electrically connected to the first fusible conductor 170 between the first end electrode 121 and the second end electrode 122 or the intermediate end of the first fusible conductor 170 through the inner electrode 181 and the heat accumulating electrode 125 The portion that is biased toward the second terminal electrode is designed such that the resistance value of the first fusible conductor 170 between the thermal storage electrode 125 and the second terminal electrode 122 may be less than or lower than the thermal storage electrode 125 and the first terminal electrode 121. Between the resistance values of the first fusible conductor 170), the other end of the heat generating component 188 is electrically connected to the terminal electrode 123. The insulating layer 160 is disposed between the heat generating component 188 and the terminal electrodes 121, 122, 124 and the heat storage electrode 125. The second fusible conductor 171 is disposed on the terminal electrode 121. When the heat generating component 188 generates heat, the first fusible conductor 170 is fused, and the second fusible conductor 171 is melted and electrically connected to the terminal electrode 124 where the fusible conductor is not disposed.

The equivalent circuit diagram of the protection element 100d of the present embodiment is similar to the circuit diagram of the protection element 8d shown in FIG. 9. The terminal electrode 121 of the present embodiment is equivalent to the input/output terminal I/O1 of the protection element 8d, and the terminal electrode 122 is equivalently protected. The input/output terminal I/O2 of the component 8d, the terminal electrode 124 is equivalent to the input/output terminal I/O4 of the protection component 8d, the terminal electrode 123 is equivalent to the output terminal O3 of the protection component 8d, and the heat storage electrode 125 is equivalent to the heat generation of the component 8d. One end N1 of the component 7 connected to the overcurrent protection element 9, the first fusible conductor 170 is equivalent to the overcurrent protection element 9, 9_1 of the protection element 8d, and the second fusible conductor 171 is equivalent to the switching element S of the protection element 8d, The heat generating assembly 188 is equivalent to the heat generating assembly 7 of the protective element 8d. The description of the related protection action in this embodiment is similar to the description of the protection element 8d in the embodiment of FIG. 9. Please refer to it here, and no further details are provided herein.

In another modification, the protection component 100d of the embodiment of the present invention may not include the insulating layer 160, wherein the heat generating component 188 may be disposed on the second surface of the insulating substrate 110 (as shown in FIG. 6D), or The inside of the insulating substrate 110 (as shown in FIG. 6E) can also achieve the same function or function or technical feature as the protection component 100d. The description of the protection action related to the modification is similar to the description of the protection element 8d of the embodiment of FIG. 9. Please refer to it yourself, and details are not described herein again.

FIG. 11A is a circuit diagram of still another protection element 8e according to an embodiment of the present invention. The circuit diagram of the protection element 8e shown in FIG. 11A is similar to the circuit of the protection element 8 shown in FIG. 5, the difference being that the protection element 8e shown in FIG. 11A further includes another overcurrent protection element 9_1, overcurrent protection. One end of the element 9_1 is coupled to one end of the overcurrent protection element 9 and the input/output terminal I/O2, and the other end of the overcurrent protection element 9_1 is coupled to one end of the heat generating component 7, and the other end of the heat generating component 7 The output terminal O3 is coupled.

The description of the related protection action of the embodiment of FIG. 11A is similar to the description of the protection element 8 of the embodiment of FIG. 5, please refer to it yourself, and details are not described herein again. What needs to be specially stated is: when heat is generated When the component 7 generates heat, the overcurrent protection element 9_1 is melted in response to the heat generated by the heat generating component 7, and at this time, the current path flowing through the heat generating component 7 is broken, causing the heat generating component 7 to flow due to no current. Stop smoking. In addition, the secondary battery pack 588 of FIG. 3A and the protective elements 8a1, 8a2 of the secondary battery pack 588a of FIG. 4 may be replaced with the protective member 8e shown in FIG. 11A.

FIG. 11B is a top view of a protection element 100e according to an embodiment of the present invention. The protection element 100e of the present embodiment includes: an insulating substrate 110, four terminal electrodes 121, 122, 123, 124, a first internal electrode 181, and a first fusible. The conductor 170, the heat generating component 188, and the second fusible conductor 171. The heat generating component 188 may be disposed in the insulating substrate 110 (refer to FIG. 6E) or on the first surface (upper surface, refer to FIG. 6B) of the insulating substrate 110 or on the second surface (lower surface of the insulating substrate 110) , can refer to Figure 6D). The terminal electrodes 121, 122, 123, 124 are disposed on the first surface of the insulating substrate. The first inner electrode 181 can be disposed on the insulating substrate 110 or in the insulating substrate 110 and electrically connected to the first end of the heat generating component 188. The second end of the heat generating component 188 is electrically connected to the fourth terminal electrode 123 or electrically connected to the fourth terminal electrode 123 through a second internal electrode (not shown) in the insulating substrate 110. The first fusible conductor 170 is disposed on the terminal electrodes 121, 122 and the first inner electrode 181. Both ends of the first fusible conductor 170 are electrically connected to the terminal electrode 121 and the first inner electrode 181, respectively. The intermediate region of the first fusible conductor 170 is electrically connected to the terminal electrode 122. When the heat generating component 188 generates heat, the first fusible conductor 170 is blown, causing the terminal electrode 121 to be electrically insulated from the terminal electrode 122, thereby electrically insulating the terminal electrode 122 from the first inner electrode 181, and causing the terminal electrode 121 to be electrically Connected to the terminal electrode 124.

In another modified embodiment, the protection component 100e of the above embodiment further includes a second fusible conductor 171 disposed on one of the first terminal electrode 121 and the third terminal electrode 124. When the heat generating component 188 is heated The second fusible conductor 171 is melted to electrically connect the first terminal electrode 121 to the third terminal electrode 124.

The circuit diagram of the protection element 100e of the present embodiment is similar to the circuit diagram of the protection element 8e shown in FIG. 11A. The terminal electrode 121 of the present embodiment is equivalent to the input/output terminal I/O1 of the protection element 8e, and the terminal electrode 122 is equivalently protected. The input/output terminal I/O2 of the element 8e, the terminal electrode 124 is equivalent to the input/output terminal I/O4 of the protection element 8e, the terminal electrode 123 is equivalent to the output terminal O3 of the protection element 8e, and the first fusible conductor 170 is equivalent to the protection element 8e The overcurrent protection elements 9 and 9_1, the second fusible conductor 171 is equivalent to the switching element S of the protection element 8e, and the heat generation assembly 188 is equivalent to the heat generation assembly 7 of the protection element 8e. The description of the related protection action in this embodiment is similar to the description of the protection element 8e in the embodiment of FIG. 11A. Please refer to it here, and no further details are provided herein.

Figure 11C is a circuit diagram showing still another protection element 8e' according to an embodiment of the present invention. The circuit diagram of the protection element 8e' shown in FIG. 11C is similar to the circuit of the protection element 8e shown in FIG. 11A, the difference being that one end of the heat generating component 7 of the protection element 8e' shown in FIG. 11C is coupled. One end of the current protection element 9 coupled to the input and output terminal I/O2 and the other end of the heat generating component 7 are coupled to one end of the overcurrent protection element 9_1. The other end of the overcurrent protection element 9_1 is coupled to the output terminal O3.

The description of the related protection action of the embodiment of FIG. 11C is similar to the description of the protection element 8e of the embodiment of FIG. 11A. Please refer to it for details, and details are not described herein again. Further, the secondary battery pack 588 of Fig. 3A and the protective members 8a1, 8a2 of the secondary battery pack 588a of Fig. 4 can also be replaced with the protective member 8e' shown in Fig. 11C.

Figure 11D is a top plan view of a protective element 100e' in accordance with an embodiment of the present invention; Figure. The protective element 100e' of the present embodiment includes: an insulating substrate 110, four terminal electrodes 121, 122, 123, 124, a first inner electrode 181, a second inner electrode 182, a heat generating component 188, a first fusible conductor 170, The second fusible conductor 171 and the fourth fusible conductor 173. The heat generating component 188 may be disposed in the insulating substrate 110 (refer to FIG. 6E) or on the first surface (upper surface, refer to FIG. 6B) of the insulating substrate 110 or on the second surface (lower surface of the insulating substrate 110) , can refer to Figure 6D). The terminal electrodes 121, 122, 123, 124 are disposed on the first surface of the insulating substrate. The first inner electrode 181 can be disposed on the insulating substrate 110 or in the insulating substrate 110 and electrically connected to the first end of the heat generating component 188. The second inner electrode 182 can be disposed on the insulating substrate 110 or in the insulating substrate 110 and electrically connected to the second end of the heat generating component 188. The first fusible conductor 170 is disposed on the terminal electrode 121 and the terminal electrode 122. Both ends of the first fusible conductor 170 are electrically connected to the terminal electrode 121 and the terminal electrode 122, respectively. The fourth fusible conductor 173 is disposed on the terminal electrode 123 and the second inner electrode 182. Both ends of the fourth fusible conductor 173 are electrically connected to the terminal electrode 123 and the second inner electrode 182, respectively. The second end of the heat generating component 188 can be electrically connected to the fourth fusible conductor 173 through the second inner electrode 182 , and the first end of the heat generating component 188 can be electrically connected to the first fusible conductor 170 through the first inner electrode 181 . When the heat generating component 188 generates heat, the first fusible conductor 170 is blown and the second fusible conductor 171 is melted, causing the terminal electrode 121 to be electrically insulated from the terminal electrode 122 and causing the terminal electrode 121 to be electrically connected to the terminal electrode 124. . At this time, the fourth fusible conductor 173 is also fused in response to the heat generated by the heat generating component 188, causing the heat generating component 188 to be electrically insulated from the terminal electrode 123.

The circuit diagram of the protection element 100e' of the present embodiment is similar to the circuit diagram of the protection element 8e' shown in FIG. 11C. The terminal electrode 121 of the present embodiment is equivalent to the input/output terminal I/O1 of the protection element 8e', and the terminal electrode 122. The input/output terminal I/O2 of the equivalent protection element 8e', the terminal electrode 124 is equivalent to the input/output terminal I/O4 of the protection element 8e', and the terminal electrode 123 is equivalently protected. The output terminal O3 of the element 8e', the first fusible conductor 170 is equivalent to the overcurrent protection element 9 of the protection element 8e', the second fusible conductor 171 is equivalent to the switching element S of the protection element 8e', and the heat generating component 188 is equivalent The heat generating component 7 of the protective element 8e', the fourth fusible conductor 173 is equivalent to the overcurrent protecting component 9_1 of the protective element 8e'. The description of the related protection action in this embodiment is similar to the description of the protection element 8e' in the embodiment of FIG. 11C. Please refer to it for details, and details are not described herein again.

In another modified embodiment, the first fusible conductor 170 and the second fusible conductor 171 in the protection component 100e' of the embodiment may be combined into only the first fusible conductor 170 (as shown in FIG. 6F). The same effect as the protective element 100e' of the embodiment.

In another variant embodiment, the protective element 100e' of the present embodiment may further comprise a third fusible conductor 172. The third fusible conductor 172 is disposed on the terminal electrode 124 and electrically connected to the terminal electrode 124. It should be noted that the area or volume or thickness of the terminal electrode 124 overlapping the third fusible conductor 172 is smaller than the area or volume or thickness of the third fusible conductor 172, so that the heat generating component 188 is molten and liquefied when it generates heat. The second fusible conductor 171 and the third fusible conductor 172 may overflow to the adjacent terminal electrodes 124, 121, causing the terminal electrodes 124, 121 to be short-circuited or electrically connected. Both the second fusible conductor 171 and the first fusible conductor 170 of the present invention may have similar design or technical features as the third fusible conductor 172.

FIG. 12A is a circuit diagram of still another protection element 8f according to an embodiment of the present invention. The circuit diagram of the protection element 8f shown in FIG. 12A is similar to the circuit of the protection element 8e shown in FIG. 11A, and the difference is that one end of the overcurrent protection element 9_1 of the protection element 8e shown in FIG. 11A is coupled. The current protection element 9 is connected to one end of the input/output terminal I/O2, and the other end of the overcurrent protection element 9_1 is coupled to one end of the heat generating component 7; in contrast, as shown in FIG. 12A One end of the overcurrent protection component 9_1 of the protection element 8f is coupled to one end of the overcurrent protection component 9 and the input and output terminal I/O1, and the other end of the overcurrent protection component 9_1 is coupled to one end of the heat generating component 7. .

The description of the related protection action of the embodiment of FIG. 12A is similar to the description of the protection element 8e of the embodiment of FIG. 11A. Please refer to it for details, and details are not described herein again. In addition, the secondary battery pack 588 of FIG. 3A and the protective elements 8a1, 8a2 of the secondary battery pack 588a of FIG. 4 may be replaced with the protective member 8f shown in FIG. 12A.

FIG. 12B is a schematic top view of a protection element 100f according to an embodiment of the invention. The equivalent circuit diagram of the protection element 100f of the present embodiment is similar to the circuit of the protection element 8f shown in FIG. 12A. The terminal electrode 121 of the present embodiment is equivalent to the input/output terminal I/O1 of the protection element 8f, and the terminal electrode 122 is equivalent. The input/output terminal I/O2 of the protection element 8f, the terminal electrode 124 is equivalent to the input/output terminal I/O4 of the protection element 8f, the terminal electrode 123 is equivalent to the output terminal O3 of the protection element 8f, and the first fusible conductor 170 is equivalent to the protection element The overcurrent protection elements 9 and 9_1 of 8f, the second fusible conductor 171 is equivalent to the switching element S of the protection element 8f, and the heat generating component 188 is equivalent to the heat generating component 7 of the protection element 8f. The description of the related protection action in this embodiment is similar to the description of the protection element 8f in the embodiment of FIG. 12A. Please refer to it for details, and details are not described herein again.

Figure 12C is a circuit diagram showing still another protection element 8f' according to an embodiment of the present invention. The circuit diagram of the protection element 8f' shown in FIG. 12C is similar to the circuit of the protection element 8e shown in FIG. 11C, the difference being that one end of the heat generation element 7 of the protection element 8e' shown in FIG. 11C is coupled to The overcurrent protection element 9 is connected to one end of the input/output terminal I/O2, and the other end of the heat generating component 7 is coupled to one end of the overcurrent protection element 9_1. In contrast, one end of the heat generating component 7 of the protective element 8f' shown in FIG. 12C is coupled to the overcurrent protection component 9 and the input/output terminal I/O1. And the other end of the heat generating component 7 is coupled to one end of the overcurrent protection component 9_1.

The description of the related protection action of the embodiment of FIG. 12C is similar to the description of the protection element 8e' of the embodiment of FIG. 11C, please refer to it yourself, and no further details are provided herein. Further, the secondary battery pack 588 of Fig. 3A and the protective members 8a1, 8a2 of the secondary battery pack 588a of Fig. 4 can also be replaced with the protective member 8f' shown in Fig. 12C.

Figure 12D is a top plan view of a protective element 100f' in accordance with an embodiment of the present invention. The equivalent circuit diagram of the protection element 100f' of the present embodiment is similar to the circuit of the protection element 8f' shown in FIG. 12C. The terminal electrode 121 of the present embodiment is equivalent to the input/output terminal I/O1 of the protection element 8f', and the terminal electrode. 122 is the input/output terminal I/O2 of the equivalent protection element 8f', the terminal electrode 124 is equivalent to the input/output terminal I/O4 of the protection element 8f', and the terminal electrode 123 is equivalent to the output terminal O3 of the protection element 8f', the first fusible The conductor 170 is equivalent to the overcurrent protection component 9 of the protection element 8f', the second fusible conductor 171 (and/or the third fusible conductor 172) is equivalent to the switching element S of the protection element 8f', and the heat generating component 188 is equivalently protected The heat generating component 7 of the element 8f', the fourth fusible conductor 173 is equivalent to the overcurrent protecting element 9_1 of the protective element 8f'. The description of the related protection action of this embodiment is similar to the description of the protection element 8f' of the embodiment of FIG. 12C. Please refer to it for details, and details are not described herein again.

In summary, the protection component and the secondary battery pack provided by the embodiments of the present invention are connected in series or in parallel in a plurality of battery component groups to achieve a high voltage and a large current or a large power secondary battery pack, if any battery When the component group is overcharged or overvoltage or overtemperature, the protection component will disconnect the charging and discharging path of the abnormal battery component group, and switch the charging and discharging path to other normal battery component groups, except that overcharge or overvoltage can be achieved. The function of over-temperature protection does not make other normal battery component groups unusable, so waste of resources can be avoided. When the charge and discharge current exceeds the guarantee When the rated current value of the component is protected, the protection component cuts off the path of the charge and discharge current to achieve the function of overcurrent protection.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and any one of ordinary skill in the art can make some changes and refinements without departing from the spirit and scope of the present invention. The scope of the invention is defined by the scope of the appended claims.

Claims (15)

A protection element, at least applicable to a secondary battery pack, comprising: a first overcurrent protection component for providing a first bidirectional current path between a first input output and a second input and output of the protection component, When the current between the first input and output terminal and the second input and output terminal is abnormal, the first overcurrent protection component turns off the first bidirectional current path for overcurrent protection; and the switching component is coupled to the current a first input and output end of the protection element and a third input and output end, and the initial state of the switching element is an open state; and a heat generating component, the first end of the heat generating component being coupled to the first overcurrent One end of the protection component is coupled to the first input output or the second input and output, and the second end of the heat generating component is coupled to the output end of the protection component, and when the heat generating component generates heat, the first The overcurrent protection element disconnects the first bidirectional current path in response to heat generated by the heat generating component, and the switching element switches to a short circuit in response to heat generated by the heat generating component To provide a second bi-directional current path between the output terminal and the third input of the first input-output terminal. The protective component of claim 1, further comprising: an insulating substrate, wherein the heat generating component is disposed on the first surface of the insulating substrate; and the first terminal electrode is disposed on the first surface of the insulating substrate The second terminal electrode is disposed on the first surface of the insulating substrate for use as the second input and output end; a third end electrode disposed on the first surface of the insulating substrate for the third input and output end; a fourth end electrode disposed on the insulating substrate for the output end; and an insulating layer Arranging between the heat generating component, the first terminal electrode, the second terminal electrode and the third terminal electrode, wherein the first overcurrent protection component is a first fusible conductor disposed at the first terminal electrode The second end electrode is electrically connected to the first end electrode and the second end electrode respectively. When the heat generating component generates heat, the first fusible conductor is blown. The first terminal electrode is electrically insulated from the second terminal electrode, and the first terminal electrode is electrically connected to the third terminal electrode. The protective element of claim 1, further comprising: an insulating substrate comprising: a first surface and a second surface, wherein the first surface and the second surface are opposite to each other; the first end electrode is disposed in the insulating The first surface of the substrate is used as the first input and output end; the second end electrode is disposed on the first surface of the insulating substrate for the second input and output end; the third end electrode, The first surface of the insulating substrate is configured to serve as the third input and output end; and the fourth end electrode is disposed on the insulating substrate to serve as the output end, wherein the heat generating component is disposed in the On the second surface of the insulating substrate, Electrically connecting the conductive electrode to the first terminal electrode or the second terminal electrode, wherein the first overcurrent protection component is a first fusible conductor disposed on the first terminal electrode and the second terminal electrode, And the two ends of the first fusible conductor are electrically connected to the first end electrode and the second end electrode respectively. When the heat generating component generates heat, the first fusible conductor is blown, so that the first end electrode The second terminal electrode is electrically insulated from the second terminal electrode, and the first terminal electrode is electrically connected to the third terminal electrode. The protection component of claim 3, further comprising: a plurality of heat collecting portions disposed inside the insulating substrate and electrically or thermally connected to the first terminal electrode and the second terminal electrode, respectively The third terminal electrode, wherein the heat collecting portions extend further adjacent to the second surface and are electrically insulated from the heat generating component to conduct heat generated by the heat generating component to the first terminal electrode, the second a terminal electrode and the third terminal electrode. The protective component of claim 1, further comprising: an insulating substrate; a first terminal electrode disposed on the first surface of the insulating substrate for the first input and output ends; and a second terminal electrode The first surface of the insulating substrate is disposed on the first surface of the insulating substrate; the third terminal electrode is disposed on the first surface of the insulating substrate to serve as the third input and output end; a fourth end electrode disposed on the insulating substrate for use as the output end The heat generating component is disposed in the insulating substrate, electrically connected to the first terminal electrode or the second terminal electrode through a conductive electrode in the insulating substrate, and electrically connected to the inner electrode through the insulating substrate a fourth end electrode, wherein the first overcurrent protection component is a first fusible conductor disposed on the first end electrode and the second end electrode, and two ends of the first fusible conductor are electrically connected to The first end electrode and the second end electrode, when the heat generating component generates heat, the first fusible conductor is blown, causing the first end electrode to be electrically insulated from the second end electrode, and causing the first The terminal electrode is electrically connected to the third terminal electrode. The protection element of claim 2, wherein the switching element comprises a second fusible conductor, and the second fusible conductor is disposed in the first end electrode and the third end electrode On one of the terminal electrodes, when the heat generating component generates heat, the second fusible conductor is melted to electrically connect the first terminal electrode to the third terminal electrode. The protection component of claim 1, further comprising: a second overcurrent protection component coupled between the first end of the heat generating component and the second input and output terminal, when the heat generating component When generating heat, the second overcurrent protection component breaks the current path of the second overcurrent protection component or the heat generating component in response to heat generated by the heat generating component, and the heat generating component stops heating. The protection component of claim 1, further comprising: a second overcurrent protection component coupled to the first overcurrent Between one end of the protection element and the first end of the heat generating component, or the second overcurrent protection element is coupled between the second end of the heat generating component and the output of the protection element When the heat generating component generates heat, the second overcurrent protection component reacts with heat generated by the heat generating component to disconnect a current path of the second overcurrent protection component or the heat generating component, thereby causing the heat generating component Stop heating. The protective component of claim 8, further comprising: an insulating substrate, wherein the heat generating component is disposed in the insulating substrate or on the first surface of the insulating substrate or the second of the insulating substrate a first end electrode disposed on the first surface of the insulating substrate for the first input and output end, and a second end electrode disposed on the first surface of the insulating substrate for a second input and output end; a third end electrode disposed on the first surface of the insulating substrate for the third input and output end; a fourth end electrode disposed on the insulating substrate for use as the And the first inner electrode is disposed on the insulating substrate or the insulating substrate, and is electrically connected to the first end of the heat generating component, wherein the second end of the heat generating component is electrically connected to the first end The fourth terminal electrode is electrically connected to the fourth terminal electrode through a second internal electrode in the insulating substrate, wherein the first overcurrent protection component and the second overcurrent protection component are first fusible conductors, and the first Fused conductor Arranging at the first end electrode, the second end electrode, and the first The first fusible conductor is electrically connected to the first end electrode, the second end electrode and the first inner electrode, respectively, and the first fusible conductor is blown when the heat generating component generates heat. The first terminal electrode is electrically insulated from the second terminal electrode, and the first terminal electrode is electrically connected to the third terminal electrode. The protective component of claim 8, further comprising: an insulating substrate, wherein the heat generating component is disposed in the insulating substrate or on the first surface of the insulating substrate or the second of the insulating substrate a first end electrode disposed on the first surface of the insulating substrate for the first input and output end, and a second end electrode disposed on the first surface of the insulating substrate for a second input and output end; a third end electrode disposed on the first surface of the insulating substrate for the third input and output end; a fourth end electrode disposed on the insulating substrate for use as the a first internal electrode disposed on the insulating substrate or the insulating substrate and electrically connected to the first end of the heat generating component; and a second internal electrode disposed on the insulating substrate or the insulating substrate And electrically connecting the second end of the heat generating component, wherein the first overcurrent protection component is a first fusible conductor, and the first fusible conductor is disposed on the first end electrode and the second end electrode First The fusible conductors are electrically connected to the first end electrode and the second end electrode, respectively, wherein the second overcurrent protection component is a fourth fusible conductor, the fourth fusible conductor Disposed on the fourth end electrode and the second inner electrode, the fourth fusible conductor is electrically connected to the fourth end electrode and the second inner electrode, respectively, wherein the second end of the heat generating component passes through the second The first electrode is electrically connected to the fourth fusible conductor, and the first end of the heat generating component is electrically connected to the first fusible conductor through the first internal electrode, and the first fusible conductor is heated when the heat generating component generates heat Being fused to electrically insulate the first terminal electrode from the second terminal electrode, and causing the first terminal electrode to be electrically connected to the third terminal electrode, the fourth fusible conductor also reacting to the heat generating component The heat generated is blown. The protection element of claim 9 or 10, wherein the switching element comprises a second fusible conductor, and the second fusible conductor is disposed in the first end electrode and the third end electrode On one of the terminal electrodes, when the heat generating component generates heat, the second fusible conductor is melted to electrically connect the first terminal electrode to the third terminal electrode. The protection element of claim 7, wherein the resistance of the second overcurrent protection component is less than the resistance of the first overcurrent protection component, or wherein the highest rated current or power of the second overcurrent protection component is greater than The highest rated current or power of the first overcurrent protection component. The protective component of claim 7 or 12, further comprising: an insulating substrate, wherein the heat generating component is disposed in the insulating substrate or on the first surface of the insulating substrate or on the insulating substrate On the second surface; a first end electrode disposed on the first surface of the insulating substrate for the first input and output end; a second end electrode disposed on the first surface of the insulating substrate for use as the second An input end; a third end electrode disposed on the first surface of the insulating substrate for the third input and output end; and a fourth end electrode disposed on the insulating substrate for the output end Wherein the first overcurrent protection component and the second overcurrent protection component are first fusible conductors disposed on the first end electrode and the second end electrode, and the two ends of the first fusible conductor are respectively electrically Connecting to the first terminal electrode and the second terminal electrode, and the first end of the heat generating component is electrically connected to the first fusible conductor between the first terminal electrode and the second terminal electrode or the first a portion of the fusible conductor intermediate end biased toward the second end electrode, wherein the switching element comprises a second fusible conductor, and the second fusible conductor is disposed at one of the first end electrode and the third end electrode On, when the heat is generated When the heat generating member, the first fusible conductor is blown and the second fuse conductor is melted so that the first electrode terminal electrically connected to the third terminal electrode. A secondary battery pack comprising: a plurality of battery element groups, each of the battery element groups including at least one chargeable and dischargeable battery element; and a plurality of any one of items 1 to 13 of the patent application scope The protection element is connected in series with the battery element groups to form a charge and discharge current path; a plurality of switch circuits, each of the switch circuits being coupled to the protection elements And the detection control circuit is configured to detect a voltage or a temperature of the battery component group, and determine a state of each of the switch circuits according to the detected voltage or temperature If the voltage or temperature of the battery element group is normal, the switch circuits are switched to an open state, and if the voltage or temperature of any one of the battery element groups is abnormal, the battery element group corresponding to the abnormality The switching circuit is switched to an on state, causing the protection element corresponding to the abnormal battery element group to disconnect the charging and discharging current path between the abnormal battery element group, and switching the charging and discharging current path to The remaining normal battery element groups in the battery element group are disconnected when an overcurrent condition occurs when a charge/discharge current flowing through any one of the protection elements exceeds a rated current value The charge and discharge current path. The secondary battery pack of claim 14, further comprising: a charge and discharge control circuit for determining whether the external device is connected according to the state of the voltage detected by the detection control circuit and the type of the external device The device transmits a charging current to the battery component groups or transmits a discharge current from the battery component groups to the external device.