JPH0721887A - Composite fuse - Google Patents

Abstract

PURPOSE:To provide a compact composite fuse in which a temperature fuse element surely covers the function of a current fuse element. CONSTITUTION:A pair of leads 12, 13 are concentrically inserted from double end openings of a cylindrical insulating case 11 and delivered in the 180 deg. opposite direction, a temperature fuse element 14 is connected to the top end of one lead 12 arranged in the insulating case 11, and a current fuse element 15 to the top end of the other lead 13. Further, the temperature fuse element 14 is directly connected to the current fuse element 15, and the double end openings of the insulating case 11 are sealed by a sealing resin 16. The temperature fuse element 14 is formed of a soluble alloy with a small resistance value which is fused when it reaches the melting point by a rise of the ambient temperature, and the current fuse element 15 is formed of a soluble alloy with a large resistance value which is fused by the self heating by overcurrent.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a composite fuse, and more particularly to a composite fuse in which a temperature fuse and a current fuse are integrated.

[0002]

2. Description of the Related Art Generally, in electric products such as electric blankets,
In order to ensure safety in use, a thermal fuse that senses an increase in ambient temperature or a current fuse that senses an overcurrent due to a short circuit or the like is attached. But,
Thermal fuses are only sensitive to rising ambient temperatures, and
Current fuses are only sensitive to overcurrent, so for example
Even if the current fuse is attached, even if the overcurrent does not occur, when the ambient temperature rises, the abnormal state cannot be sensed, which is dangerous. for that reason,
Both the temperature fuse and the current fuse are attached. However, two fuses have to be attached, which sometimes causes a problem in terms of installation space and cost.

Therefore, in recent years, a composite fuse in which a temperature fuse and a current fuse are integrated so as to detect not only an increase in ambient temperature but also an overcurrent has been favored.

In this composite fuse, for example, as shown in FIG. 5, a pair of leads (2) and (3) are coaxially inserted through openings at both ends of a cylindrical insulating case (1) and led out in opposite directions by 180 °. Then, connect the thermal fuse element (4) to the tip of one lead (2) arranged in the insulating case (1) and connect the current fuse element (5) to the tip of the other lead (3). In addition, the thermal fuse element (4) and the current fuse element (5) are connected via the electrode (7), and both ends of the insulating case (1) are sealed with a sealing resin (6). [Actual development 62-1
No. 50856]. This Thermal Fuse Element (4)
Is made of a fusible alloy having a small resistance value that melts when reaching the melting point due to an increase in ambient temperature, and the current fuse element (5) is made of a fusible alloy having a large resistance value that melts by self-heating due to overcurrent.

In addition to the axial type structure described above, there is a radial type composite fuse shown in FIG. As shown in the figure, this composite fuse has a pair of parallel leads (2) (3) inserted from the open end of a bottomed cylindrical insulating case (1 ') and led out in the same direction.
The thermal fuse element (4) and the current fuse element (5) are connected to the tips of the leads (2) (3) arranged in the insulating case (1), and between the fuse elements (4) and (5). Are connected with a bent intermediate lead (8), and the open end of the insulating case (1 ') is sealed with a sealing resin (6'). The temperature fuse element (4) and current fuse element (5) A partition wall (9) is arranged between them.

[0006]

By the way, in the above-mentioned conventional composite fuse, if the ambient temperature rises during operation without the occurrence of overcurrent, the thermal fuse element (4)
Fuses when it senses an increase in ambient temperature, and conversely, if an overcurrent occurs even if the ambient temperature does not rise, the current fuse element (5) senses the overcurrent and fuses by self-heating. As a result, the functions are mutually exerted.

Since the current fuse element (5) has a wide temperature range in which it melts due to self-heating, the current fuse element (5) does not always melt immediately even within this temperature range. Therefore, in addition to the independent functions of the temperature fuse element (4) and the current fuse element (5) described above, in this composite fuse, when the current fuse element (5) self-heats due to overcurrent, The temperature fuse element (4) senses the temperature rise of the element (5), and the temperature fuse element (4) immediately melts to complement the function of the current fuse element (5) with the temperature fuse element (4). It is possible to do.

However, in the composite fuse of the structure shown in FIG. 5, the electrode (7) is interposed between the temperature fuse element (4) and the current fuse element (5), and in the composite fuse shown in FIG. Since the intermediate lead (8) and the partition wall (9) are interposed between the fuse elements (4) and (5), the temperature fuse element (4) must detect the temperature rise due to self-heating of the current fuse element (5). Has become an obstacle. In addition, the above structure requires a space for accommodating an intervening member between the temperature fuse element (4) and the current fuse element (5), which makes it difficult to reduce the size.

Therefore, the present invention has been proposed in view of the above problems, and an object thereof is to provide a compact composite fuse in which the temperature fuse element surely complements the function of the current fuse element. is there.

[0010]

As a technical means for achieving the above object, the present invention provides a current fuse element made of a fusible alloy that melts by self-heating due to an overcurrent and a fuse that melts when the ambient temperature rises. A thermal fuse element made of a molten alloy is housed in a single insulating case, and a pair of leads connected to the temperature and current fuse element are led out in a sealed state from the insulating case. And the temperature fuse element are directly joined.

It is desirable that the current and temperature fuse elements are directly joined in the state where one temperature fuse element is arranged between the two current fuse elements.

When the composite fuse is an axial type,
A pair of leads are coaxially inserted through the openings of both ends of the cylindrical insulating case and lead out in 180 ° opposite directions, and a current fuse element and a temperature fuse element are directly joined between the lead tips arranged in the insulating case. Are connected, and both ends of the insulating case are sealed with a sealing resin.

In the case of the radial type, a pair of parallel leads are inserted from the open end of the bottomed cylindrical insulating case and led out in the same direction, and directly joined between the lead tips arranged in the insulating case. The current fuse element and the temperature fuse element are connected to each other, and the open end of the insulating case is sealed with a sealing resin.

[0014]

In the composite fuse according to the present invention, since the temperature fuse element and the current fuse element are directly joined to each other, when the current fuse element self-heats due to overcurrent during operation, the temperature rise of the current fuse element is controlled. The function of the current fuse element can be surely complemented by the temperature fuse element because the fuse element can be accurately sensed and the temperature fuse element is immediately blown.

[0015]

EXAMPLE An example of a composite fuse according to the present invention will be described with reference to FIGS. 1 and 2 show an axial type embodiment, and FIGS. 3 and 4 show a radial type embodiment.

The composite fuse of the embodiment shown in FIG. 1 has a pair of leads (12) (1) extending from openings at both ends of a cylindrical insulating case (11).
3) is inserted coaxially and led out in the opposite direction by 180 °, and the thermal fuse element (14) is connected to the tip of one lead (12) arranged in the insulating case (11),
The current fuse element (15) is connected to the tip of the other lead (13), and the temperature fuse element (14) and the current fuse element (15) are directly joined to each other to open both ends of the insulating case (11). Has a structure in which is sealed with a sealing resin (16). As in the conventional case, the thermal fuse element (14) is made of a fusible alloy with a small resistance value that melts when it reaches the melting point due to an increase in ambient temperature, and the current fuse element (15) melts by self-heating due to overcurrent. It consists of a fusible alloy with a large resistance value.

Here, the temperature fuse element (14) and the current fuse element (15) and the fuse elements (14) and (15) and the leads (12) and (13) are joined, for example, by the joining. It may be performed by instantaneously heating only a part to generate heat and locally melting.

In this way, the thermal fuse element (1
When the current fuse element (15) self-heats due to overcurrent during operation by directly joining the current fuse element (15) to the temperature fuse element (15), 1
4) can be accurately sensed by its thermal fuse element (1
Since 4) melts immediately, the function of the current fuse element (15) can be reliably complemented by the temperature fuse element (14).

The composite fuse of the embodiment of FIG. 2 is obtained by adding another current fuse element (15) to the embodiment of FIG. 1, and two current fuse elements (15) (15) are provided.
With one thermal fuse element (14) sandwiched between the current fuse elements (15) (15)
And a thermal fuse element (14) are coaxially and directly joined to each other.

As described above, the two current fuse elements (15) (15) are combined into one temperature fuse element (14).
With such a structure, the temperature fuse element (14) can more accurately detect the temperature rise due to self-heating due to the overcurrent of the current fuse element (15) (15).

In the above embodiment, the leads (12) (13)
The axial type structure having 180 ° opposite directions and arranged coaxially has been described, but the present invention is not limited to this, and the radial type structure shown in FIGS. 3 and 4 is also applicable. Applicable.

The composite fuse of the embodiment shown in FIG. 3 has a pair of leads (12) extending from the open end of a cylindrical bottomed insulating case (11 ').
Insert (13) in parallel and lead out in the same direction, connect the thermal fuse element (14) to the tip of one lead (12) arranged in the insulating case (11 '), and connect the other lead. The current fuse element (1
5) and connect this thermal fuse element (1
4) and the current fuse element (15) are directly joined,
It has a structure in which the open end of the insulating case (11 ') is sealed with a sealing resin (16').

The composite fuse of the embodiment shown in FIG. 4 has a structure in which one thermal fuse element (14) is arranged between two current fuse elements (15) (15) and is inserted in an insulating case (11 '). The current fuse elements (15) and (15) are connected to the tips of the leads (12) and (13),
The thermal fuse element (14) is directly joined so as to straddle the both current fuse elements (15, 15).

[0024]

According to the present invention, in a composite fuse in which a temperature fuse and a current fuse are integrated, the temperature fuse element and the current fuse element have independent functions, and the current fuse element self-operates due to overcurrent. When heat is generated, the temperature rise of the current fuse element can be accurately detected by the temperature fuse element, and the function of the temperature fuse element complementing the function of the current fuse element becomes reliable, improving reliability and ensuring safety. We can provide rich and compact composite fuses.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of a composite fuse according to the present invention.

FIG. 2 is a sectional view showing a modified example of the composite fuse shown in FIG.

FIG. 3 is a sectional view showing another embodiment of the present invention.

4 is a cross-sectional view showing a modified example of the composite fuse of FIG.

FIG. 5 is a sectional view showing a conventional example of a composite fuse.

FIG. 6 is a sectional view showing another conventional example of a composite fuse.

[Explanation of symbols]

 11, 11 'Insulation case 12, 13 Lead 14 Thermal fuse element 15 Current fuse element 16, 16' Sealing resin

Claims (4)

[Claims] 1. A current fuse element made of a fusible alloy that melts by self-heating due to overcurrent and a temperature fuse element made of a fusible alloy that melts when the ambient temperature rises are housed in a single insulating case. In a composite fuse derived with a pair of leads connected to a temperature and current fuse element sealed from an insulating case,
A composite fuse characterized in that the current fuse element and the temperature fuse element are directly joined. 2. The composite fuse according to claim 1, wherein the current and temperature fuse elements are directly joined in a state where one temperature fuse element is arranged between the two current fuse elements. 3. A pair of leads are coaxially inserted through the openings of both ends of a cylindrical insulating case and led out in 180 ° opposite directions,
3. The current fuse element and the thermal fuse element, which are directly joined, are connected between the ends of the leads arranged in the insulating case, and the openings at both ends of the insulating case are sealed with a sealing resin. Composite fuse. 4. A current fuse element directly inserted between a pair of leads extending in the same direction by inserting a pair of parallel leads from an open end of a bottomed cylindrical insulating case, and a current fuse element. 3. The composite fuse according to claim 1, wherein the composite fuse is connected to a thermal fuse element and the open end of the insulating case is sealed with a sealing resin.