KR101995217B1 - Fuse resistor assembly and method manufacturing fuse resistor assembly - Google Patents

Abstract

The present invention relates to a fuse resistor assembly and a manufacturing method thereof which can maintain sturdy coupling of a resistor and a fuse. According to the present invention, the fuse resistor assembly comprises: a resistor including a resistor rod, first and second resistor caps positioned on both ends of the resistor rod, a resistor wire to connect the first and second resistor caps, and a conductive resistor lead wire connected to the first resistor cap; and a fuse including a fuse rod, first and second fuse caps positioned on both ends of the fuse rod, a fusible body coated on the fuse rod to electrically connect the first and second fuse caps and to be disconnected by overcurrent, a conductive first fuse lead wire connected to the first fuse cap, and a conductive second fuse lead wire connected to the second fuse cap. The resistor rod includes a hollow space wherein one side thereof is opened in a longitudinal direction and the other side thereof is closed. The second resistor cap includes a cap hole corresponding to a hollow section of the hollow space. The fuse rod, the first and second fuse caps, and the first fuse lead wire of the fuse are inserted along the hollow space and the cap hole, and the first fuse lead wire is bent to join one end thereof to the first fuse cap and join the other end thereof to the second resistor cap.

Description

Fuse resistor assembly and method manufacturing fuse resistor assembly

The present invention relates to a fuse resistor assembly, and more particularly, to a fuse resistor assembly in which a resistor and a fuse are bonded, and a manufacturing method thereof.

In general, micro-fuses are installed at the power input terminals of electronic products such as televisions and videos to prevent circuit burnout and fire of the board by breaking the circuit when inflow of overcurrent. Acts as a circuit breaker.

This fuse is a material of the fusible element layer, compared to other metals, and has a relatively low intrinsic resistivity and a high temperature coefficient and a very high melting point. It can be stably melted within a predetermined time, and is used instead of the existing fuses for home appliances such as large TVs and monitors using high current.

However, in the conventional fuse resistor assembly, since the resistors and the fuses are connected in a row, the bulky and the fuses are connected in a row, the coupling of the resistors and the fuses is easily broken due to external shock, and thus the durability is weak.

The problem to be solved by the present invention relates to a fuse resistor assembly and a method for manufacturing the same that allows the resistor and the fuse to be firmly maintained while connecting the resistor and the fuse in series.

The fuse resistor assembly according to the present invention for solving the above problems is a resistance rod, the first resistance cap and the second resistance cap located at both ends of the resistance rod, connecting the first resistance cap and the second resistance cap A resistor including a resistor and a conductive resistor lead connected to the first resistor cap; And a fuse rod, a first fuse cap and a second fuse cap positioned at both ends of the fuse rod, and coated on the fuse rod to electrically connect the first fuse cap and the second fuse cap and to be disconnected by an overcurrent. And a fuse including a conductive first fuse lead wire connected to the first fuse cap and a conductive second fuse lead wire connected to the second fuse cap, wherein the resistance rod has one side in a length direction. An open and closed hollow portion, the second resistance cap includes a cap hole corresponding to the hollow cross section of the hollow portion, and the fuse includes the fuse rod, the first fuse cap, and the second fuse cap. And the first fuse leader line is inserted along the hollow part and the cap hole, and the first fuse lead wire is bent so that one end is joined to the first fuse cap and the other end is joined to the second resistance cap. And a gong.

The other end of the first fuse lead wire may be bonded to the second resistance cap by at least one of spot welding, laser welding, and soldering.

The first fuse lead wire includes a “S” shaped bent structure, one end of the “S” shaped lead wire is joined to the first fuse cap, and the other end of the “S” shaped lead wire is formed of the first fuse lead wire. 2 is characterized in that it is bonded with the resistance cap.

A fuse protection layer coated to protect the fuse rod, the first fuse cap, the second fuse cap, and the soluble body; And a fuse insulation layer coated to insulate the current flowing through the first fuse lead wire and the second fuse lead wire from an external component.

The soluble body is coated with a tin component on the surface of the fuse rod, it characterized in that the cut according to the trimming pattern for adjusting the melting time of the soluble body.

The trimming pattern is cut by varying at least one or more of the number of cutting points and the cutting shape.

A charging layer filling the hollow part of the resistor into which the fuse is inserted; And a protective tube surrounding the resistor filled with the filling layer.

Method for manufacturing a fuse resistor assembly according to the present invention for solving the above problems comprises the steps of manufacturing a resistor and a fuse bonded to the resistor; And inserting the fuse into the hollow portion of the resistor to bond the resistor and the fuse in series, wherein the manufacturing of the fuse includes: coating a soluble material on a fuse rod formed in a longitudinal direction; Coupling conductive first and second fuse caps to both ends of the fuse rod coated with the soluble substance; Connecting a conductive first fuse lead to one end of the first fuse cap and connecting a conductive second fuse lead to one end of the second fuse cap; Coating a fuse protection layer to protect the fuse rod, the first fuse cap, the second fuse cap, and the soluble body; And coating a fuse insulation layer to insulate the current flowing through the first fuse lead wire and the second fuse lead wire from external components.

The bonding of the resistor and the fuse may include bending one end of the first fuse lead wire to the first fuse cap to have a 180 degree angle; Inserting the fuse rod, the first fuse cap, the second fuse cap, and the bent first fuse leader line into the hollow part; And bending the other end of the first fuse lead wire that is joined to the second resistance cap to 90 degrees or more, and bonding the other end to the second resistance cap.

In the bonding of the other end of the first fuse lead wire and the second resistance cap, the first fuse lead wire and the second resistance cap may be bonded by at least one of spot welding, laser welding, and soldering. do.

The manufacturing of the fuse may further include cutting the soluble substance after adjusting the melting time of the soluble substance after coupling the first fuse cap and the second fuse cap to both ends of the fuse rod. It is characterized by.

The cutting of the soluble body may include cutting the soluble body by varying at least one of the number of cutting points and the cutting shape.

Inserting the fuse into the hollow part of the resistor and bonding the fuse; then filling the hollow part of the resistor into which the fuse is inserted using a filling layer; And surrounding the resistor with the filling layer by using a protective tube.

According to the present invention, the resistor and the fuse are bonded to each other, but the fuse rod, the first fuse cap, the second fuse cap, and the first fuse leader wire, which are components of the fuse, are inserted into the hollow part of the resistor, and the first fuse lead wire A fuse resistance assembly composed of a resistor and a fuse is formed by forming a structure in which one end is bent to be joined to the first fuse cap and the other end of the first fuse lead wire is bent to the second resistance cap to be connected in series with the fuse inserted into the resistor. It is possible to minimize the volume of and to improve the durability of the fuse resistor assembly in spite of the volume reduction.

In addition, by forming a trimming pattern for the soluble body formed in the fuse, it is possible to appropriately adjust the melting time according to the overcurrent of the fuse resistor assembly.

1 is a cross-sectional view showing a fuse resistor assembly according to an embodiment of the present invention.
2A is a perspective view illustrating the resistor shown in FIG. 1, and FIG. 2B is a cross-sectional view of the resistor shown in FIG. 1.
3A is a perspective view of the fuse shown in FIG. 1, and FIG. 3B is a cross-sectional view of the fuse shown in FIG. 1.
4 is a reference diagram illustrating a trimming pattern according to film cutting of a soluble body according to the present invention.
5 is a reference view of an embodiment comparing the melting time according to the number of cutting points.
6 is a reference view of an embodiment comparing the melting time according to the point shape of the cutting shape.
7 is a reference view of another embodiment comparing the melting time according to the line shape among the cutting shapes.
8 is a flowchart illustrating a method of manufacturing a fuse resistor assembly according to the present invention.
9A and 9B are reference diagrams illustrating an actual operation process for describing a manufacturing process of a fuse resistor assembly.
FIG. 10 is a flowchart of an embodiment for describing the manufacturing of the fuse illustrated in FIG. 8.
FIG. 11 is a flowchart of an exemplary embodiment for explaining a step of coupling the resistor and the fuse shown in FIG. 8 in series.
12 is a reference diagram illustrating a bent state at one end and the other end of the first fuse lead wire.

Description of the present invention is only an embodiment for structural or functional description, the scope of the present invention should not be construed as limited by the embodiments described in the text. That is, since the embodiments may be variously modified and may have various forms, the scope of the present invention should be understood to include equivalents capable of realizing the technical idea.

When a component is referred to as being "connected" to another component, it should be understood that there may be other components in between, although it may be directly connected to the other component. On the other hand, when a component is referred to as being "directly connected" to another component, it should be understood that there is no other component in between.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Generally, the terms defined in the dictionary used are to be interpreted as being consistent with the meanings in the context of the related art, and should not be interpreted as having ideal or excessively formal meanings unless clearly defined in the present invention.

1 is a cross-sectional view showing a fuse resistor assembly 10 of one embodiment according to the present invention.

Referring to FIG. 1, the fuse resistor assembly 10 includes a resistor 100 and a fuse 200.

The resistor 100 includes a conductive resistive component and functions to limit the inrush current.

The resistor 100 includes a resistor rod, a first resistor cap and a second resistor cap positioned at both ends of the resistor rod, a resistor wire connecting the first resistor cap and the second resistor cap, and a conductive wire connected to the first resistor cap. It includes a resistance lead wire.

FIG. 2A is a perspective view of the resistor 100 illustrated in FIG. 1, and FIG. 2B is a cross-sectional view of the resistor 100 illustrated in FIG. 1.

2A and 2B, the resistor 100 may include a resistor rod 110, a first resistor cap 120, a second resistor cap 130, a resistor line 140, and a resistor lead 150. have.

The resistance rod 110 may include a shape having a cylinder or a prism, and may be formed of a ceramic material. The resistance rod 110 includes a hollow portion 110-1 formed in the longitudinal direction. The hollow part 110-1 has a structure in which one side of the resistance rod 110 is opened and the other side is closed to form a hole up to a predetermined depth. In the case of FIG. 2A, the hollow cross section perpendicular to the longitudinal direction of the hollow part 110-1 is circular, but this is merely illustrative, and may be a polygon (eg, a rectangle, a pentagon, a hexagon, or an arc). Etc.) may be a cross-sectional shape.

The first resistance cap 120 may be inserted into and coupled to one end of the resistance rod 110. To this end, the first resistance cap 120 may be in the form of a cap in which one end of the cylindrical structure (eg, cylindrical structure, square cylinder structure) is closed. The first resistance cap 120 is conductive.

The second resistance cap 130 may also be inserted into and coupled to the other end of the resistance rod 110. To this end, the second resistance cap 130 may be in the form of a cap having a cylindrical structure (for example, cylindrical structure, square cylinder structure). In particular, the second resistance cap 130 includes a cap hole 130-1 corresponding to the hollow cross section of the hollow part 110-1 in the resistance rod 110. Here, unlike the first resistor cap 120, the cap hole 130-1 is a hole through which the fuse 200 to be described later can be inserted even if the second resistor cap 130 is inserted into the resistance rod 110. Has a structure. The cross-sectional structure of the cap hole 130-1 may be circular or polygonal so as to coincide with the hollow cross section of the resistance rod 110. The second resistance cap 130 has the same conductivity as the first resistance cap 120.

The resistance line 140 is a line for connecting the first resistance cap 120 and the second resistance cap 130 while spirally wrapping the surface of the resistance rod 110. The resistance line 140 includes a resistance component that is generated by overcurrent. One end of the resistance line 140 is bonded to one side of the first resistance cap 120, and the other end of the resistance line 140 is bonded to one side of the second resistance cap 130.

The resistance lead wire 150 is bonded to the outside of the first resistance cap 120. The resistance lead wire 150 may be bonded to the first resistance cap 120 by spot welding, laser welding, or soldering. Unlike the related art, the resistor 100 includes only one resistor lead wire 150.

The fuse 200 cuts off the circuit connection due to heat or overcurrent. The fuse 200 is coated on a fuse rod, a first fuse cap and a second fuse cap positioned at both ends of the fuse rod, and the fuse rod to electrically connect the first fuse cap and the second fuse cap. And a soluble body broken by an overcurrent, a conductive first fuse lead connected to the first fuse cap, and a conductive second fuse lead connected to the second fuse cap. In the fuse 200, a fuse rod, the first fuse cap, the second fuse cap, and the first fuse leader line are inserted along the hollow portion and the cap hole.

3A is a perspective view of the fuse 200 illustrated in FIG. 1, and FIG. 3B is a cross-sectional view of the fuse 200 illustrated in FIG. 1.

3A and 3B, the fuse 200 includes a fuse rod 210, a soluble body 220, a first fuse cap 230, a second fuse cap 240, and a first fuse lead wire 250. The second fuse lead wire 260 may include a fuse protection layer (not shown) and a fuse insulating layer (not shown).

The fuse rod 210 may include a shape having a cylinder or a prismatic pillar, and may be formed of a ceramic material.

The soluble body 220 is a conductive film formed on the surface of the fuse rod 210, a tin layer may be formed as a fusible element layer on a plating layer made of nickel alloy or copper alloy.

The soluble body 220 may form a trimming pattern by performing a film cut called trimming on the surface according to a desired resistance value. Film cutting can be done via laser cutting or diamond cutting.

The trimming pattern may be cut by varying at least one of the number of cutting points and the cutting shape. In this case, the cutting shape may be a point type, a straight shape or a spiral shape, or a combination thereof.

4 is a reference diagram illustrating a trimming pattern according to the coating cut of the soluble body 220 according to the present invention. FIG. 4A illustrates a trimming pattern in the form of points, and FIG. 4B illustrates a trimming pattern in the form of lines.

The trimming pattern may bring a difference in the melting time of the soluble body 220 according to the overcurrent according to the number of cutting points or the difference in the cutting shape. The difference in melting time of the soluble body 220 according to the trimming pattern will be described with reference to FIGS. 5 to 7.

FIG. 5 is a reference view of an embodiment comparing the melting time according to the number of cutting points, FIG. 6 is a reference view of an embodiment comparing the melting time according to the point shape among the cutting shapes, and FIG. 7 is a line shape among the cutting shapes. Is a reference diagram of another embodiment comparing the melting time according to the present invention.

Referring to FIG. 5, it can be seen that the melting time gradually decreases as the number of cutting points for cutting the film increases. In addition, referring to FIG. 6, it can be seen that the melting time decreases as the cutting point increases in the length direction of the cutting shape for cutting the film. In addition, referring to Figure 7, it can be seen that the melting time decreases as the line length of the straight or spiral of the cutting shape for cutting the film is increased. Therefore, by selecting the trimming pattern of the soluble body 220 according to the design purpose, the melting time with respect to the overcurrent of the fuse 200 can be adjusted.

The first fuse cap 230 and the second fuse cap 240 may be inserted into and coupled to both ends of the fuse rod 210 in which the soluble body 220 is formed. To this end, the first fuse cap 230 and the second fuse cap 240 may be in the form of a cap having one end closed as a cylindrical structure (for example, a cylindrical structure and a square cylinder structure).

The first fuse lead wire 250 and the second fuse lead wire 260 are respectively joined to the outside of the first fuse cap 230 and the second fuse cap 240. The first fuse lead wire 250 and the second fuse lead wire 260 may be joined to the first fuse cap 230 and the second fuse cap 240 by spot welding, laser welding, soldering, or the like. The first fuse lead wire 250 and the second fuse lead wire 260 are each electrically conductive.

Meanwhile, as illustrated in FIGS. 3A and 3B, one end A of the first fuse lead wire 250 is joined to one side of the first fuse cap 230 in a bent state, and the first fuse lead wire 250 The other end B of) is also joined to one side of the second resistance cap 130 in a bent state. The first fuse lead wire 250 is bent in an “S” shape twice, so that the hollow part 110-1 and the second part of the resistance rod 110 in which the fuse 200 constitutes the resistor 100. In order to form a structure for being connected in series with the resistor 100 while being inserted along the cap hole 130-1 of the resistor cap 130. Since the first fuse lead wire 250 includes a “S” shaped bending structure, one end of the “S” shaped lead wire is joined to the first fuse cap 230, and the other end of the “S” shaped lead wire is formed. 2 is bonded to the resistance cap 130. At this time, the fuse 200 is connected to the resistor 100 in series, the other end of the first fuse lead wire 250 is bonded to the second resistor cap 130 by at least one of spot welding, laser welding and soldering. Can be.

The fuse protection layer coats the fuse rod 210, the first fuse cap 230, and the second fuse cap 240 in which the soluble body 220 is formed. Accordingly, the fuse protection layer protects the coating of the soluble body 220 and protects the surfaces of the first fuse cap 230 and the second fuse cap 240. In addition, the fuse protection layer has an insulation function for insulation with the resistor 100.

The fuse insulation layer surrounds the first fuse lead wire 250 and the second fuse lead wire 260 coupled to the first fuse cap 230 and the second fuse cap 240, respectively. The fuse insulation layer coats the first fuse lead wire 250 and the second fuse lead wire 260 to insulate the current flowing through the first fuse lead wire 250 and the second fuse lead wire 260 from external components. However, the coating of the fuse insulation layer is excluded at the portion where the first fuse lead wire 250 and the second resistance cap 130 are bonded to each other.

The fuse resistor assembly 10 is wrapped with a filling layer (not shown) to protect the resistor 100 to which the fuse 200 is bonded. That is, in the state in which the fuse 200 is inserted into the resistor 100, the hollow part 110-1 of the resistor 100 is filled with the filling layer. The filling layer fills the empty space between the fuse 200 and the resistor 100 inserted into the hollow part 110-1 of the resistor 100, and also surrounds the outside of the resistor 100. Here, the filling layer may be a filling layer made of epoxy or silicon.

In addition, the fuse resistor assembly 10 may include a protection tube (not shown) to protect the resistor 100 and / or the charge layer in which the charge layer is charged. The protective tube surrounds the filling layer surrounding the resistor 100, and also functions to insulate the outside (such as other components).

8 is a flowchart illustrating a method of manufacturing a fuse resistor assembly according to the present invention. 9A and 9B are reference diagrams illustrating an actual operation process for describing a manufacturing process of a fuse resistor assembly.

First, a resistor and a fuse bonded to the resistor are manufactured (step S300).

The resistor may include a resistor rod, a first resistor cap, a second resistor cap, a resistor line, and a resistor lead as shown in FIGS. 2A and 2B. The resistor body forms a hollow part to a predetermined depth in the longitudinal direction of the resistor rod after manufacturing the resistance rod made of ceramic material. Thereafter, after the resistance lead wire is bonded to the first resistance cap, the first resistance cap and the second resistance cap to which the resistance lead wire is bonded are coupled to both ends of the resistance rod. At this time, the second resistance cap to be coupled includes a cap hole corresponding to the hollow cross section of the resistance rod. Thereafter, the resistance wire is used to connect the first resistance cap and the second resistance cap while spirally wrapping the surface of the resistance rod.

Meanwhile, as illustrated in FIGS. 3A and 3B, the fuse may include a fuse rod, a fuse, a first fuse cap, a second fuse cap, a first fuse lead wire, a second fuse lead wire, a fuse protection layer, and a fuse insulation. It may comprise a layer.

FIG. 10 is a flowchart of an embodiment for describing the manufacturing of the fuse illustrated in FIG. 8.

First, the soluble material is coated on the fuse rod formed in the longitudinal direction (S400 step). A tin layer may be formed as a fusible element layer on a plating layer made of nickel alloy or copper alloy on the surface of the fuse rod.

After the step S400, the first fuse cap and the second fuse cap having conductivity are coupled to both ends of the fuse rod having the plating layer formed thereon (step S402). The fuse caps may each be in the form of a cap in which one end of a cylindrical structure (eg, a cylindrical structure, a square cylinder structure) is closed.

After step S402, the soluble material is cut to adjust the blow time of the fuse (step S404). In the cutting of the soluble body, the plating layer may be cut by varying at least one of the number of cutting points and the cutting shape according to a trimming pattern. In this case, the cutting shape may be at least one of a point type, a straight type and a spiral, or a combination thereof. Depending on the trimming pattern due to the number of cutting points or the difference in cutting shape, a difference occurs in the melting time of the plating layer due to the overcurrent. However, step S402 is not an essential step, and may proceed to step S406 after step S402 without forming a trimming pattern on the soluble material.

After the step S404, a conductive first fuse lead wire is connected to one end of the first fuse cap, and a conductive second fuse lead wire is connected to one end of the second fuse cap (step S406). The first fuse lead wire and the second fuse lead wire may be respectively bonded to the first fuse cap and the second fuse cap by spot welding, laser welding, soldering, or the like.

After the step S406, the fuse rod constituting the fuse, the first fuse cap, the second fuse cap, and is coated with a fuse protective layer to protect the soluble body (step S408). The fuse protection layer protects the coating of the soluble body, protects the surfaces of the first fuse cap and the second fuse cap, and insulates the resistor and the fuse.

After the step S408, the fuse insulating layer is coated to insulate the current flowing through the first fuse lead wire and the second fuse lead wire from the external components (step S410). The fuse insulating layer insulates current flowing through the first fuse lead wire and the second fuse lead wire from external components (eg, resistors).

Again, after step S300, the fuse is inserted into the hollow part of the resistor, and the resistor and the fuse are coupled in series (step S302). In the bonding of the resistor and the fuse, the resistor and the fuse may be bonded by at least one of spot welding, laser welding, and soldering.

FIG. 11 is a flowchart of an exemplary embodiment for explaining a step of coupling the resistor and the fuse shown in FIG. 8 in series.

One end of the first fuse lead wire is bent to have a 180 degree angle (S500). 12 is a reference diagram illustrating a bent state at one end and the other end of the first fuse lead wire. Referring to FIG. 12, one end A joined to the first fuse cap is bent by 180 degrees at an angle joined to the first first fuse cap. However, the bent angle is exemplary, and the angle bent based on 180 degrees may be increased or decreased.

After the step S500, the fuse rod, the first fuse cap, the second fuse cap, and the bent first fuse leader line are inserted into the hollow part (S502). In order for the fuse rod, the first fuse cap, the second fuse cap, and the bent first fuse leader line to be inserted into the hollow part of the resistance cap, the hollow cross section of the hollow part may include the above components constituting the fuse. It should have a cross-sectional area that can be as high as possible, and a depth of the hollow part to which all the external shapes of the first fuse cap, the second fuse cap, and the bent first fuse leader line constituting the fuse can be inserted.

After the step S502, the other end of the first fuse lead wire is bent at 90 degrees or more to be bonded to the second resistance cap (step S504). Referring to FIG. 12, the other end B of the first fuse cap illustrates a state of bending at least 90 degrees at an angle joined with the first second fuse cap. However, the bent angle is exemplary, and the angle bent based on 90 degrees may be increased or decreased. The other end of the first fuse lead wire and the second resistance cap are joined by at least one of spot welding, laser welding, and soldering.

Again, after step S302, the hollow portion of the resistor into which the fuse is inserted is filled with the filling layer, and the outside of the resistor is wrapped with the filling layer (step S304). The filling layer fills the void space between the fuse and the resistor inserted into the hollow portion of the resistor, and also surrounds the outside of the resistor. Here, the filling layer may be a filling layer made of epoxy or silicon.

After step S304, the protection tube is filled with a protective tube using the surroundings (step S306). The protective tube surrounds the filling layer to prevent damage to the filling layer filling the hollow portion of the resistor or surrounding the outside of the resistor. The protective tube may be formed by molding through injection or molding using a tube.

While the above has been shown and described with respect to preferred embodiments of the present invention, the present invention is not limited to the specific embodiments described above, it is usually in the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

10: fuse resistance assembly
100: resistor
110: resistive load
120: first resistance cap
130: second resistance cap
140: resistance wire
150: resistance lead wire
200: fuse
210: fuse load
220: soluble
230: first fuse cap
240: second fuse cap
250: first fuse lead wire
260: second fuse lead wire

Claims (13)

A resistance rod, a first resistance cap and a second resistance cap positioned at both ends of the resistance rod, a resistance wire connecting the first resistance cap and the second resistance cap, and a conductive resistance lead wire connected to the first resistance cap. Resistor comprising a; And
A fuse rod, a first fuse cap and a second fuse cap positioned at both ends of the fuse rod, and a soluble body coated on the fuse rod to electrically connect the first fuse cap and the second fuse cap and to be disconnected by an overcurrent. And a fuse including a conductive first fuse lead wire connected to the first fuse cap and a conductive second fuse lead wire connected to the second fuse cap.
The resistance rod includes a hollow portion in which one side is opened in the longitudinal direction and the other side is closed,
The second resistance cap includes a cap hole corresponding to the hollow cross section of the hollow portion,
The fuse,
The fuse rod, the first fuse cap, the second fuse cap, and the first fuse lead wire are inserted along the hollow part and the cap hole, and the first fuse lead wire is bent so that one end of the first fuse cap And a second end bonded to the second resistance cap. The method according to claim 1,
And the other end of the first fuse lead wire is joined to the second resistance cap by at least one of spot welding, laser welding, and soldering. The method according to claim 1,
The first fuse lead wire,
A “S” shaped bending structure, one end of the “S” shaped lead wire is joined to the first fuse cap, and the other end of the “S” shaped lead wire is joined to the second resistance cap. A fuse resistor assembly, characterized in that. The method according to claim 1,
A fuse protection layer coated to protect the fuse rod, the first fuse cap, the second fuse cap, and the soluble body; And
And a fuse insulation layer coated to insulate the current flowing through the first fuse lead wires and the second fuse lead wires from external components. The method according to claim 1,
The soluble body,
The surface of the fuse rod is coated with a tin component,
Fuse resistance assembly, characterized in that cut according to the trimming pattern for adjusting the melting time of the soluble body. The method according to claim 5,
The trimming pattern is,
A fuse resistor assembly, which is cut by varying at least one of the number of cutting points and the cutting shape. The method according to claim 1,
A charging layer filling the hollow part of the resistor into which the fuse is inserted; And
And a protective tube surrounding the resistor filled with the filling layer. Manufacturing a resistor and a fuse bonded to the resistor; And
Inserting the fuse into the hollow part of the resistor, thereby connecting the resistor and the fuse in series;
Manufacturing the fuse,
Coating a soluble body on a longitudinally formed fuse rod;
Coupling conductive first and second fuse caps to both ends of the fuse rod coated with the soluble substance;
Connecting a conductive first fuse lead to one end of the first fuse cap and connecting a conductive second fuse lead to one end of the second fuse cap;
Coating a fuse protection layer to protect the fuse rod, the first fuse cap, the second fuse cap, and the soluble body; And
And coating a fuse insulation layer to insulate the current flowing through the first fuse lead wires and the second fuse lead wires from external components. The method according to claim 8,
Joining the resistor and the fuse,
The resistor is connected to a resistor rod, a first resistor cap and a second resistor cap positioned at both ends of the resistor rod, a resistor wire connecting the first resistor cap and the second resistor cap, and a conductive wire connected to the first resistor cap. If include the resistance lead wire,
Bending one end of the first fuse lead wire to be bonded to the first fuse cap at an angle of 180 degrees;
Inserting the fuse rod, the first fuse cap, the second fuse cap, and the bent first fuse leader line into the hollow part;
And bending the other end of the first fuse lead wire that is joined to the second resistance cap to 90 degrees or more to bond the second resistance cap to the second resistance cap. The method according to claim 9,
Joining the other end of the first fuse lead wire and the second resistance cap,
And the first fuse lead wire and the second resistor cap are joined by at least one of spot welding, laser welding and soldering. The method according to claim 10,
Manufacturing the fuse,
After coupling the first fuse cap and the second fuse cap to both ends of the fuse rod, cutting the soluble body to adjust the fusion time of the soluble body. Manufacturing method. The method according to claim 11,
Cutting the soluble body,
The method of manufacturing a fuse resistor assembly, characterized in that for cutting the soluble body by varying at least one of the number of cutting points and the cutting shape. The method according to claim 8,
Inserting the fuse into the hollow part of the resistor and bonding the fuse; then filling the hollow part of the resistor into which the fuse is inserted using a filling layer; And
And using a protective tube to surround the resistor filled with the filling layer.

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