JP4267332B2 - Protective element - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a protection element called a temperature fuse with a resistor.
[0002]
[Prior art]
A thermal fuse with a resistor has a fusible alloy piece, is equipped with a resistor that blows off the fusible alloy piece by energization heat generation, and is used in combination with an abnormality detection circuit to cause abnormalities in equipment such as abnormal voltage. Detection is performed by a detection circuit, and by this detection, the resistor is energized to generate heat, and the generated heat is used to cut off the fusible alloy piece, thereby interrupting energization of the device. Further, the melting point of the fusible alloy piece can be set to the allowable temperature of the device, and when the device reaches the allowable temperature, the fusible alloy piece can be melted and used to prevent abnormal heat generation of the device and thus fire.
[0003]
FIG. 7 (a) is a drawing showing an example of a conventional thermal fuse with a resistor, and FIG. 7 (b) is a cross-sectional view of FIG. 7 (b).
In FIG. 7, 1 'is an insulating substrate such as a ceramic substrate, and 20' to 23 'are electrodes provided on the insulating substrate by printing and baking a conductive paste. Reference numeral 4 'denotes a fusible alloy piece connected by welding or the like between the first electrode 21' and the second electrode 22 ', and is also joined to the intermediate electrode 20'. Reference numeral 3 'denotes a film resistor connected between the third electrode 23' and the intermediate electrode 20 ', which is provided by printing and baking of a resistance paste. Reference numeral 5 ′ denotes an overcoat for the film resistor 3 ′, which is provided by printing and baking a glass paste, and is generally an outer layer that is approximately 300 μm to 1000 μm larger than the outer layer of the film resistor 3 ′. 6 'is a flux applied to the soluble alloy piece. Reference numeral 8 'denotes an insulating cover.
[0004]
In order to manufacture the above temperature fuse with a resistor, a step of contacting the electrode pattern mesh screen to print the electrode and then baking, a step of contacting the membrane resistance pattern mesh screen to print the film resistance and then baking , A step of printing the overcoat by contacting the mesh screen for overcoat and then baking, a step of setting the resistance value of the film resistance to a predetermined value by trimming as necessary before or after the overcoat printing / baking step, It is necessary to go through the steps of connecting a fusible alloy piece to the electrode and then applying flux, connecting the lead conductor to each electrode, sealing with a case cover, etc. In order to prevent the occurrence of cracks in the film, in order to prevent the film resistance from being altered by the chemical action of the flux, When it is effective to prevent changes.
[0005]
The operation mechanism of the temperature-provided thermal fuse is as follows.
That is, normally, the membrane resistance is not energized, and the fusible alloy piece is inserted between the device and the power source and energized. When an abnormal condition occurs, the membrane resistance is energized and heated, and this generated heat melts the fusible alloy piece, and the molten alloy is spheroidized and divided by wetting and spreading to the electrode in the presence of the already melted flux. The non-return cut-off is terminated by cooling and solidifying the divided alloy.
In addition, if the melting point of the fusible alloy piece is set to the allowable temperature of the device, the fusible alloy piece is melted when the device reaches the allowable temperature, and the molten alloy is transferred to the electrode in the presence of the molten flux. The spheroidization is divided by the spread of wetting, the energization to the equipment is cut off by this division, the equipment temperature is lowered, and the non-returning cutoff is terminated by the cooling and solidification of the cutting alloy.
In the thermal fuse with a resistor shown in FIG. 7, the intermediate electrode 20 ′ is also involved in the division of the fusible alloy piece 4. The larger the area S of the intermediate electrode 20 ′ where the overcoat end 51 e ′ is not applied, the larger the spheroidized division. Can be promoted.
[0006]
[Problems to be solved by the invention]
The overcoating protrusion margin with respect to the membrane resistance edge requires a certain distance or more in order to protect the above-described membrane resistance, and requires a seal margin of at least 300 μm.
However, in FIG. 7, the effective area where the soluble alloy piece can spread out on the intermediate electrode toward the membrane resistance side is proportional to the distance from the soluble alloy piece 4 ′ to the overcoat end 51e ′. In addition, the effective electrode area with respect to wetting and spreading is reduced by a distance corresponding to the seal allowance at one end of the overcoat, and the cutting performance is deteriorated accordingly.
In the thermal fuse with a resistor, the applicant first printed and baked the film resistance, and then printed and baked the intermediate electrode so that one end of the intermediate electrode covered one end of the film resistor, and then overcoated. Has already been proposed (see Patent Document 1). In this manufacturing process, the electrode screen mesh screen is brought into contact with the electrode to be printed, and then the film resistance pattern mesh screen is printed. It is only explained that the process of printing the film resistance by contacting the film and then baking the film alternately is performed, and the distance from one end of the overcoat to the soluble alloy piece does not change, and the soluble alloy piece is divided. The performance problem remains unresolved.
[0007]
[Patent Document 1]
JP-A-10-125514
[0008]
The object of the present invention is to ensure that the splitting performance of the fusible alloy piece is well guaranteed even in the case where the outer diameter of the fusible alloy piece is relatively large with respect to the intermediate electrode in the thermal fuse with a resistor. There is to do.
[0009]
[Means for solving the problems]
The protection element according to claim 1 has a heating element, a soluble alloy piece, and an intermediate electrode on one side of the substrate, one end of the heating element is connected to one end of the intermediate electrode, Intermediate electrode at a distancePredeterminedThis is a protective element in which a fusible alloy piece is bonded to the site and an overcoat is applied on the heating element, with one end of the intermediate electrode covering one end of the heating element, and one end of the overcoat covering the end of the intermediate electrode Covering the intermediate electrodePredeterminedDistance L from the part to one end of the overcoat₁But the intermediate electrodePredeterminedDistance L from the part to one end of the heating element₂On the other hand, L₁> L₂It is characterized by being −300 μm.
[0010]
The protective element according to claim 2 is L₁≧ L₂The protective element according to claim 1, wherein the protective element according to claim 3 has a covering distance L3 of one end portion of the overcoat with respect to one end portion of the intermediate electrode of 0.6 mm or less. The protective element according to claim 1 or 2, wherein
[0011]
The protection element according to claim 4 has a heating element, a soluble alloy piece, and an intermediate electrode on one side of the substrate, and one end portion of the heating element is connected to one end portion of the intermediate electrode. Intermediate electrode at a distancePredeterminedThis is a protective element in which a fusible alloy piece is bonded to the part, and an overcoat is applied on the heating element. One end of the heating element protrudes from one end of the overcoat, and one end of the intermediate electrode protrudesAboveIt is characterized by covering one end of the heating element and one end of the overcoat.
[0012]
The protective element according to claim 5 is characterized in that the overcoat extends along at least a part of an electrode edge of a portion where an electrode connected to a heating element and another electrode face each other. It is a protection element in any one of Claims 1-4.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1A is a drawing showing an embodiment of a protection element according to claim 1, and FIG. 1B is a cross-sectional view of FIG.
In FIG. 1, reference numeral 1 denotes a heat-resistant insulating substrate such as a ceramic substrate. Reference numerals 21 and 22 denote a first electrode and a second electrode provided by printing and baking a conductive paste, and are provided with lead conductor attachment portions 210 and 220. Similarly, reference numerals 23 and 20 denote a third electrode and an intermediate electrode, and reference numeral 230 denotes a lead conductor attachment portion of the third electrode 23. Reference numeral 3 denotes a membrane resistor. As shown in FIG. 1B, one end 31 of the membrane resistor 3 is covered with one end 201 of the intermediate electrode 20, and the other end 32 of the membrane resistor 3 is covered with the third electrode 23. Covered with one end 232. Reference numeral 4 denotes a fusible alloy piece, which is connected between the first electrode 21 and the second electrode 22 by welding or the like and is joined to the intermediate electrode 20 by welding or the like. 5 is an overcoat for the membrane resistance 3, and the distance L from the membrane resistance one end 31e to the fusible alloy piece 4₂, The distance L from the overcoat end 51e to the fusible alloy piece 4₁The
[Expression 1]
L₁> L₂-300μm
It is as. 6 is a flux applied to the soluble alloy piece 4. Reference numerals 71 to 73 are lead conductors connected to the respective lead conductor attachment portions 210 to 230 of the first electrode 21 to the third electrode 23 by welding or the like, and it is preferable to use spot resistance welding for welding.
Reference numeral 8 denotes an insulating covering, for example, a structure in which a sealant such as an epoxy resin is applied, or a structure in which a protective plate 85 is fixed on the sealant layer 84 as shown in FIG. 2 (B), the cover 81 is placed on the substrate 1, the lead conductors 71 (72, 73) are drawn from the lead conductor lead-out holes 821 of the frame 82, and sealed with an adhesive 83. can do.
[0014]
In the embodiment shown in FIG. 1, the dimensions and arrangement of the first to third electrodes, the membrane resistance, and the soluble alloy piece are the same as those in the conventional example of FIG. 7, and the distance from the soluble alloy piece 4 to one end of the membrane resistance 31e. L₂Are equal, only the dimensions of the overcoat 5 are different. Thus, in the conventional example shown in FIG. 7, since the protruding distance of the overcoat end 51e ′ from the film resistance end 31e ′ is 300 μm or more, the distance from the overcoat end 51e ′ to the soluble alloy piece 4 ′ is increased. Distance L₁Is at most
[Expression 2]
L₁= L₂-300μm
It is.
On the other hand, in the embodiment shown in FIG. 1, the distance L from the overcoat end 51 e to the fusible alloy piece 4.₁L₁> L₂Since it is set to −300 μm, the distance from one end of the overcoat to the soluble alloy piece can be made longer than in the conventional example. Therefore, in the embodiment, as compared with the conventional example, the effective electrode area for the molten alloy in the intermediate electrode to wet and spread toward the film resistance side can be widened, and the spheroidizing and cutting performance of the soluble alloy piece can be improved.
[0015]
In claim 1, the distance L from the overcoat end 51e to the fusible alloy piece 4₁Is the distance (reference distance) L from the fusible alloy piece 4 to one end of the membrane resistance 31e₂Even smaller (L₁<L₂Even), L₁> L₂As described above, as long as the condition of −300 μm is satisfied, the spheroidizing performance of the fusible alloy piece 4 can be improved as compared with the conventional example.
[Equation 3]
L₁≧ L₂
If this is the case, the effective distance L for the molten alloy in the intermediate electrode against wetting and spreading toward the membrane resistance side₁Can be lengthened so much, L₁≧ L₂Is desirable.
[0016]
In the embodiment shown in FIG. 1, the sealing performance of the one end portion 31 of the membrane resistor depends on the overlapping interface between the one end portion 201 of the intermediate electrode and the one end portion 51 of the overcoat, and the arrangement and dimensions of the intermediate electrode and the membrane resistor are fixed. The overlap interface distance L3 is given by the protrusion margin of the overcoat end 51e with respect to the intermediate electrode piece end 201e. If the overlap interface distance L3 is too long, the 20 molten alloy in the intermediate electrode wets and spreads toward the film resistance side. Effective distance L to₁And the effect of improving the spheroidizing performance is reduced, so that the overlap interface distance L3 is normally set to 600 μm or less.
[0017]
The protection element according to claim 1 includes: (a) a step of abutting a mesh screen of a membrane resistance pattern to print a membrane resistance and then baking; (b) abutment of a mesh screen of an electrode pattern to print an electrode. (C) A step of printing the overcoat by abutting the mesh screen for overcoat and then baking, (d) Trimming of the film resistance by trimming as necessary before or after printing or baking of the overcoat. A step of setting the resistance value to a predetermined value, (e) a step of connecting a fusible alloy piece between the first and second electrodes, and then applying a flux; (f) spot welding of the lead conductor to the first to third electrodes. The process of connecting, (g) The process of sealing with the case cover proceeds in the order of the processes, and it takes time to connect the lead conductors, and there is a possibility that the fusible alloy pieces may be thermally affected, for example If soldering is used, it is safe to connect the lead conductor to the first to third electrodes before connecting the fusible alloy pieces to the first and second electrodes and then applying the flux. is there.
[0018]
According to the protection element of the present invention, a sign for an abnormality of the device is detected, and the membrane resistance is energized and heated in accordance with this detection, and the energization to the device is interrupted by fusing the soluble alloy piece with the generated heat. This energization cut off also cuts off the energization to the membrane resistance. For example, when a lithium ion secondary battery is charged, an increase in voltage that occurs during overcharging is detected. Along with this detection, the membrane resistance is energized to generate heat, and the generated alloy piece is melted to charge the secondary battery. Can be disconnected from the vessel.
[0019]
FIG. 3 shows a protection circuit for a secondary battery using the temperature fuse with resistor of the above embodiment.
In FIG. 3, S is a charger, and A is a lithium ion secondary battery. B denotes a detection operation circuit unit, in which a Zener diode D is connected to the base of the transistor Tr via a resistor R, an emitter is grounded, and a positive side of the Zener diode D is connected to a high voltage side of the circuit. C represents the protective element of the above embodiment, in which the first electrode 21 and the second electrode 22 are connected between the charger S and the secondary battery A, and the third electrode 23 is connected to the collector of the transistor Tr. .
The breakdown voltage of the Zener diode D is set low with respect to the voltage rise that occurs when the secondary battery is overcharged. When the voltage rises due to overcharge, a base current flows through the transistor Tr and a large collector current flows, causing the film to flow. The resistor 3 generates heat, and the generated heat is transmitted to the fusible alloy piece 4 through the intermediate electrode 20, the fusible alloy piece 4 is melted, and the molten alloy 4 receives the active action of the already melted flux while the intermediate electrode 20 and The first electrode 21 and the second electrode 22 on both sides thereof are wetted and spread, and are divided between the intermediate electrode 20 and the first electrode 21 and between the intermediate electrode 20 and the second electrode 22, and the membrane resistance 3 is removed from the battery. Blocked.
In the protection element according to the present invention, the melting point of the fusible alloy piece is selected as a device, for example, the protection temperature of the secondary battery (desired temperature at 80 ° C. to 120 ° C.), and the protection device is substantially at the device temperature. If the device is installed in thermal contact with the device so that the temperature can be raised, the device can be de-energized at the protection temperature, and the device can be prevented from overheating and thus causing a fire when the temperature exceeds the protection temperature.
[0020]
After the operation of the protective element described above, the electrodes electrically connected by the fusible alloy pieces before the operation are electrically disconnected, and the circuit voltage acts between the electrodes, resulting in a short distance between the electrodes. In some places, re-conduction due to a flashover may occur. In order to prevent this re-conduction, as shown in FIG. 4, at least a portion where the intermediate electrode 20 or the third electrode 23 connected to the membrane resistance and the other electrode (first electrode or second electrode) face each other An extension portion 511, 512 or 513 of the overcoat 5 can be formed along a part of the edge portion of the electrode, and insulation reinforcement can be performed so as to prevent the flashing.
[0021]
5 (a) is a drawing showing an embodiment of a protection element according to claim 4, and FIG. 5 (b) is a drawing showing a cross section of FIG. 5 (b).
In FIG. 5, reference numeral 1 denotes a heat-resistant insulating substrate such as a ceramic substrate. Reference numeral 3 denotes a film resistance provided on the insulating substrate, which is provided by printing and baking of a resistance paste as described above. Reference numeral 5 denotes an overcoat for the membrane resistor 3, and one end 31 of the membrane resistor 3 is projected from the overcoat one end 51e by a predetermined distance a, and the other end 32 of the membrane resistor 3 is projected from the overcoat other end 52e by a predetermined distance. Only b is projected. Reference numeral 21 denotes a first electrode, 22 denotes a second electrode, 20 denotes an intermediate electrode, and 23 denotes a third electrode, which are provided by printing and baking a conductive paste as described above. Among these electrodes, the third electrode is electrically connected to the membrane resistor 3 by being brought into contact with the protrusion b. One end (membrane resistance side end) 201 of the intermediate electrode 20 is positioned so as to exceed the one end 51e of the overcoat 5, and the intermediate electrode 20 contacts the film resistor 3 at the protrusion margin a of the film resistor one end 31. Have been electrically connected.
4 is a fusible alloy piece, which is connected between the first electrode 21 and the second electrode 22 by welding or the like, and the intermediate portion is joined to the intermediate electrode 20 by welding or the like. 6 is a flux applied to the soluble alloy piece 4. Reference numerals 71, 72 and 73 are lead conductors connected to the lead conductor mounting portion 210 of the first electrode 21, the lead conductor mounting portion 220 of the second electrode 22, and the lead conductor mounting portion 230 of the third electrode 23 by welding or the like. It is preferable to use spot resistance welding for welding.
Reference numeral 8 denotes an insulating covering, and a structure in which the cover is adhered to the substrate with an adhesive in the surrounding frame as in FIGS. 2A and 2B described above, or a structure in which a sealing agent such as an epoxy resin is applied. Alternatively, the protective plate can be fixed on the sealant layer.
[0022]
FIG. 6 shows the cross section of the protection element shown in FIG. 5B in comparison with the cross section of the conventional example shown in FIG.
In FIG. 6, the positions 31e and 31e 'at one end of the membrane resistor are the same, and the distance L from the fusible alloy pieces 4 and 4' to this position.₂Are the same dimensions. The contact margin a between the one end portion 31 (31 ') of the membrane resistor and the one end portion 201 (201') of the intermediate electrode is made the same, and the contact electric resistance therebetween is made equal.
In the conventional protective element shown in FIG. 7, as described above, the overcoat end 51e ′ protrudes at least 300 μm from the film resistance end 31e ′, so that it is effective for spreading the molten soluble alloy toward the film resistance side. Distance at most L₂-300 μm. On the other hand, in the thermal fuse with a resistor according to claim 4, one end portion 201 of the intermediate electrode 20 is positioned beyond the overcoat end 51e, and the wet and spread of the melted soluble alloy toward the film resistance side The effective distance L of a conventional thermal fuse with a resistor is₂Can be larger than −300 μm.
Therefore, according to the protection element according to claim 4, it is possible to guarantee the spheroidizing performance of the fusible alloy piece superior to the conventional example.
[0023]
The protection element according to claim 4 is manufactured by (a) a step of abutting a mesh screen of a membrane resistance pattern to print a membrane resistance and baking it, and (b) abutment of an overcoat mesh screen to print an overcoat. (C) a step of printing the electrode by contacting the mesh screen of the electrode pattern and then baking it; (d) a step of setting the resistance value of the film resistance to a predetermined value by trimming, if necessary; e) a step of connecting a soluble alloy piece to the first and second electrodes and then applying a flux; (f) a step of connecting a lead conductor to the first to third electrodes by spot welding; and (g) sealing with a case cover. In the case of using soldering, which requires time to connect the lead conductors and may have a negative effect on the fusible alloy pieces, such as soldering, The step of connecting over de conductor, it is safe to connect the fusible alloy piece to the electrode and then with the previous step of applying a flux.
[0024]
The usage pattern of the protection element according to claim 4 is the same as the usage pattern of the protection element according to claim 1 described above.
In any of the above-described embodiments, if the cross-sectional area of the lead conductor 73 of the third electrode 23 is reduced, the heat conduction outflow of the heat generated by the conduction of the film resistor 3 through the lead conductor 73 is suppressed, and the membrane resistance 3 Since the heat generation speed can be increased and the operation speed of the protective element can be further increased, the cross-sectional area of the lead conductor connected to the third electrode can be changed to other lead conductors (lead conductors connected to the first electrode and the second electrode). In contrast, it is preferably about 0.8 to 0.5 times. In this case, if the cross-sections of all the lead conductors are made square with the same height and the cross-sectional area is reduced by narrowing the width, the heights of all the lead conductors can be made equal, and an insulating plate or insulating case for the cover can be mounted. When placed, it can be horizontal without tilting, and all lead conductors can be easily manufactured from a punched lead frame.
[0025]
In any of the above embodiments, the lead conductor is provided. However, the first to third electrodes can be turned to the back side of the substrate through the side surface of the substrate to be a chip type.
[0026]
In the present invention, the overcoat material is an insulator and is not limited to a glass coat, and a synthetic resin coat such as an epoxy resin coat can also be used.
In the present invention, the electrode material is not only a fired type comprising a mixture of conductive particles, glass frit and an organic solvent, but also a thermosetting type comprising a mixture of conductive particles, a thermosetting resin (for example, epoxy resin) and a solvent. As the conductive particles, metal particles such as silver, palladium, gold, and copper, carbon, and the like can be used.
In the present invention, the film resistance material is not only a baking type composed of a mixture of resistance particles, glass frit and an organic solvent, but also a thermosetting type composed of a mixture of resistance particles, a thermosetting resin (for example, epoxy resin) and a solvent. It is also possible to use metal oxide particles such as ruthenium oxide particles as resistance particles. In addition, it is possible to use a Ti—Si resistance paste.
In the present invention, the insulating substrate can be used without particular limitation as long as it is insulative and has heat resistance capable of withstanding the formation of electrodes and film resistance, such as a ceramic plate such as an alumina ceramic plate, a heat resistant plastic plate, A glass fiber reinforced plastic plate, a metal plate having an insulating film on the surface, or the like can be used.
[0027]
The present invention has a heating element, a fusible alloy piece, and an intermediate electrode on one side of a substrate, one end of the heating element is connected to one end of the intermediate electrode, and an intermediate portion separated from the one end of the heating element by a predetermined distance. Any protective element in which a fusible alloy piece is bonded to the electrode part and an overcoat is applied on the heating element can be applied without being limited by the number of heating elements or the number of electrodes.
[0028]
The vertical x horizontal dimension of the insulating substrate of the temperature fuse with resistor according to the present invention is normally (4.0 to 10.0) mm x (4.0 to 10.0) mm. The arrangement pattern and dimensions of the electrodes and film resistors are set according to the rated current and the rated voltage.
A conventional thermal fuse with a resistor whose rating is 10 A × 50 V and the arrangement pattern of the membrane resistance, electrode, overcoat, and soluble alloy piece is as shown in FIG. 7 has a vertical x horizontal dimension of 6 on the insulating substrate. 0.0 mm x 6.0 mm, vertical x horizontal dimension of membrane resistance 1.8 mm x 1.0 mm, vertical x horizontal dimension of intermediate electrode 1.7 mm x 1.2 mm, overcoat vertical x horizontal dimension 2.4 mm × 1.6 mm, soluble alloy piece operating temperature 135 ° C., specific resistance 15 μΩcm, alloy composition Sn 46.5% -Pb 29.8% -Cd 16.7% -In 7%, outer diameter 500 μmφ, one end of overcoat The effective distance from the molten alloy piece to approximately 500 μm.
However, the alloy composition contains metallic elements harmful to living systems such as Cd and Pb, and there is a problem in environmental conservation. Therefore, when the alloy composition is changed to Bi52% -Sn46% -In2%, which does not contain Cd or Pb, and the operating temperature is the same as described above, the specific resistance is 34 μΩcm and the Sn—Pb—Cd—In alloy composition It is necessary to make the outer diameter of the soluble alloy piece 1.5 times (√34 / √15) under the same rating, and the effective distance of 500 μm is that of the soluble alloy piece. It is shortened by the increase in the outer diameter, and the wet area of the molten alloy in the intermediate electrode is decreased, so that the performance of the operation becomes remarkable.
On the other hand, in the thermal fuse with a resistor according to the present invention, as will be apparent from the examples to be described later, compared to the conventional product, the effective wettability distance of the molten alloy in the intermediate electrode can be increased by 300 μm or more, that is, 60 μm or more. Therefore, even if the cadmium-free and lead-free alloys that are adaptable to the environment are used for the alloy composition, a sufficient effective wet area can be secured, and good operating performance can be guaranteed.
[0029]
【Example】
Evaluation of operation performance is based on a reference temperature fuse (with the membrane resistance omitted from the examples and comparative examples, and the length of the intermediate electrode is 2.8 mm, and the area of the intermediate electrode is extremely wide compared to the examples and comparative examples. In addition, the wettability of the fusible alloy at the intermediate electrode was maximized, and the other points were the same as in the examples and comparative examples.
With respect to the operating temperature, the number of samples was 50, and the oil was immersed in an oil bath at a heating rate of 1 ° C./min while energizing a current of 0.1 ampere. The temperature was taken as the operating temperature.
[0030]
[Example 1]
1. The configuration shown in FIG. 1 is that the insulating substrate 1 is made of an alumina ceramic plate having a length × width × thickness of 6.0 mm × 6.0 mm × 0.64 mm, the membrane resistance 3 is set to a length × width × 1.8 mm × 1.0mm is formed by printing and baking a ruthenium oxide resistance paste, and electrodes 20 to 23 are formed by printing and baking a silver conductive paste, and the first electrode (excluding the lead conductor mounting portion) 21 vertical x horizontal The dimensions are 1.7 mm x 0.6 mm, the vertical x horizontal dimension of the second electrode (excluding the lead conductor mounting portion) 22 is 1.7 mm x 0.6 mm, and the vertical x horizontal dimension of the intermediate electrode 20 is 1.7 mm. × 1.2 mm, the overlap margin between the intermediate electrode one end 201 and the membrane resistance one end 31 is 300 μm, the distance between the first electrode 21 and the intermediate electrode 20 is 0.5 mm, and the second electrode 22 and the intermediate electrode 20 Set the interval to 0. And mm, provided an overcoat 5 by printing and baking glass paste and overcoat end 51e and membrane resistance end 31e as a substantially same position. The meltable alloy piece 4 has an alloy composition of Sn 48%, In 2%, balance Bi with a specific resistance of 34 μΩ · cm, an outer diameter of 750 μm, a length of 3.4 mm (resistance value 0.0026Ω), and is overcoated. The fusible alloy piece 4 was disposed at a position where the distance from the end 51 e to the center line of the fusible alloy piece 4 was 900 μm and welded to the first electrode 21, the second electrode 22 and the intermediate electrode 20. For flux 6, a composition comprising 80 parts by weight of rosin, 20 parts by weight of stearic acid, and 1 part by weight of diethylamine hydrobromide was used. All the lead conductors used were copper wires having a cross section of 1.0 mm × 0.3 mm, and the insulating covering 8 was provided by coating with an epoxy resin.
The operating temperature was measured and found to be 135 ± 1 ° C.
[0031]
[Comparative Example 1]
Example 1 except that the overlap margin between the intermediate electrode piece end portion 201 ′ and the membrane resistance one end portion 31 ′ is 300 μm and the seal margin of the overcoat 5 ′ with respect to the membrane resistor one end portion 31 ′ is 300 μm. And the same.
The operating temperature was measured and found to be 141 ± 3 ° C.
A reference temperature fuse was created and its operating temperature was measured and found to be 134 ± 1 ° C.
[0032]
In Example 1, compared with Comparative Example 1, the effective wet distance of the soluble alloy in the intermediate electrode is 300 μm longer, and the effective wet distance (of the intermediate electrode portion not covered by the overcoat between the soluble alloy piece and the overcoat) Even if the distance) varies depending on the outer diameter of the fusible alloy piece, it is about 500 μm, so that the effective wet distance is about 130% longer in Example 1 than in Comparative Example 1.
In the reference temperature fuse, since the area of the intermediate electrode is sufficiently wide, the wet spread of the molten alloy can be substantially maximized. In the first embodiment, the operation temperature is substantially equal to the operation temperature of the reference temperature fuse. Since it is the same, the wet spread of the molten alloy at the intermediate electrode is almost the same as that of the reference temperature fuse, and it can be evaluated that the operation performance is excellent.
However, in Comparative Example 1, it is recognized that the division of the molten alloy was delayed and the oil temperature increased during that time, and it was clear that the effective wet area of the intermediate electrode was insufficient.
[0033]
[Example 2]
5, the insulating substrate 1 is made of an alumina ceramic plate having a length × width × thickness of 6.0 mm × 6.0 mm × 0.64 mm, and the membrane resistance 3 is set to a length × width of 1.8 mm × Formed by printing and baking ruthenium oxide resistance paste to 1.0 mm, and by overprinting and baking glass paste, overcoat 5 has a protrusion margin a of film resistance one end 31 from overcoat end 51e to 300 μm, overcoat etc. The protrusion b of the film resistor other end portion 32 from the end 52e is provided to be 300 μm. The electrode is formed by printing and baking a silver-based conductive paste, and the first electrode (excluding the lead conductor mounting portion) 21 has a vertical x horizontal dimension of 1.7 mm x 0.6 mm, and the second electrode (lead conductor mounting portion is Excluding) 22 vertical x horizontal dimensions of 1.7 mm x 0.6 mm, intermediate electrode 20 vertical x horizontal dimensions of 2.0 mm x 1.2 mm, and overlap of intermediate electrode one end 201 and one end of membrane resistance 31 The margin a is 300 μm, the distance between the first electrode 21 and the intermediate electrode 20 is 0.5 mm, the distance between the second electrode 22 and the intermediate electrode 20 is 0.5 mm, and the gap between the membrane resistance one end 31e and the intermediate electrode piece 201e The distance was set to 600 μm. As in Example 1, the fusible alloy piece 4 has an alloy composition of Sn 48%, In 2%, balance Bi with a specific resistance of 34 μΩ · cm and an outer diameter of 750 μm and a length of 3.4 mm (resistance value 0.0026Ω). The soluble alloy piece 4 is disposed at a position where the distance from the membrane resistance one end 31 e to the center line of the soluble alloy piece 4 is 900 μm, and is welded to the first electrode 21, the second electrode 22 and the intermediate electrode 20. did. The flux 6, the lead conductors 71 to 73, and the insulating cover 8 were the same as in Example 1.
In Example 2, the effective wet distance of the soluble alloy in the intermediate electrode is approximately 900 μm longer than in Comparative Example 1, and in Example 2, the effective wet distance is approximately 400% longer than in Comparative Example 1.
The operating temperature was measured and found to be 134 ± 1 ° C.
[0034]
In Example 2, since the operating temperature is the same as the operating temperature of the reference temperature fuse, wetting and spreading of the molten alloy at the intermediate electrode occurs substantially the same as that of the reference temperature fuse and has excellent operating performance.
[0035]
Example 3
Same as Example 1 except that the alloy composition of Sn 53%, In 2% and the balance Bi of specific resistance 31 μΩ · cm is used for the fusible alloy piece, and the outer diameter is 720 μm in order to make the resistance value equal to that of Example 1. It was. The operating temperature was measured and found to be 143 ± 2 ° C.
[0036]
[Comparative Example 2]
Comparative Example 1 except that the alloy composition of Sn 53%, In 2% and the balance Bi with a specific resistance of 31 μΩ · cm was used for the fusible alloy piece and the outer diameter was 720 μm in order to make the resistance value equal to that of Example 3. Same as above. The operating temperature was measured and found to be 147 ± 2 ° C.
A reference temperature fuse was prepared by using an alloy composition of Sn 53%, In 2%, and the remaining Bi having a specific resistance of 31 μΩ · cm for the fusible alloy piece, and its operating temperature was measured to be 143 ± 2 ° C.
In Example 3, since the operating temperature is the same as the operating temperature of the reference temperature fuse, the wetting and spreading of the molten alloy at the intermediate electrode is similar to that of the reference temperature fuse, and has excellent operating performance.
However, in Comparative Example 2, similarly to Comparative Example 1, it is recognized that the division of the molten alloy was delayed and the oil temperature increased during that time, and it was clear that the effective wet area of the intermediate electrode was insufficient.
[0037]
【The invention's effect】
According to claim 1, the substrate has a membrane resistance and soluble alloy piece and an intermediate electrode on one side of the substrate, one end of the membrane resistance is connected to one end of the intermediate electrode, and a predetermined distance from the one end of the membrane resistance is set. In a thermal fuse with a resistor, in which a fusible alloy piece is bonded to the separated intermediate electrode portion and overcoated on the film resistance, the intermediate electrode is printed and baked on the conventional thermal fuse with a resistor shown in FIG. By simply switching the process and the process of printing and baking film resistance, and adjusting the overcoat printing dimensions so as to widen the distance between one end of the overcoat and the soluble alloy piece, It is possible to provide a temperature fuse with a resistor that can increase the wet effective distance and can guarantee good operation performance even when the outer diameter of the fusible alloy piece is relatively large with respect to the intermediate electrode.
[0038]
The thermal fuse with a resistor according to claim 4 has a film resistance and a soluble alloy piece and an intermediate electrode on one side of the substrate, one end of the film resistance is connected to one end of the intermediate electrode, and one end of the film resistance A fusible alloy piece is bonded to the intermediate electrode part at a predetermined distance from the film, an overcoat is applied on the film resistance, one end of the film resistance protrudes from one end of the overcoat, and the end of the intermediate electrode piece protrudes from the film resistance Since one end part and one end part of the overcoat are covered, the effective distance of wetting with respect to the molten alloy at the intermediate electrode can be increased by increasing the dimension that the end part of the intermediate electrode covers the one end part of the overcoat. It is possible to provide a thermal fuse with a resistor that can guarantee good operation performance even when the diameter is relatively large with respect to the intermediate electrode.
[0039]
According to the fifth aspect, it is possible to insulate and reinforce the voltage acting between the electrodes when the fusible alloy piece is divided, to prevent re-conduction after the division, and to ensure stable interruption.
[0040]
According to the present invention, under the same fuse dimensions, the effective wetting distance of the intermediate electrode can be increased to improve the operating characteristics. Therefore, the intermediate electrode dimensions can be reduced to ensure the same operating performance. It is also possible to reduce the size.
[Brief description of the drawings]
1 is a drawing showing a protection element according to claim 1;
FIG. 2 is a drawing showing different examples of the insulating covering of the protective element according to the present invention.
FIG. 3 is a drawing showing an example of a usage state of a protection element according to the present invention.
FIG. 4 is a drawing showing a protection element according to claim 5;
FIG. 5 is a drawing showing a protective element according to claim 5;
FIG. 6 is a drawing used for comparison between a protection element according to claim 5 and a conventional example.
FIG. 7 is a view showing a conventional protection element.
[Explanation of symbols]
1 Insulating substrate
20 Intermediate electrode
3 Membrane resistance
31 One end of membrane resistance
31e One end of membrane resistance
4 soluble alloy pieces
5 Overcoat
51 One end of overcoat
51e One end of overcoat
6 Flux
8 Insulation cover

Claims (5)

A predetermined portion of the intermediate electrode having a heating element, a soluble alloy piece and an intermediate electrode on one side of the substrate, one end of the heating element being connected to one end of the intermediate electrode, and a predetermined distance from the one end of the heating element Is a protective element in which a fusible alloy piece is bonded to the heating element and overcoated on the heating element, with one end of the intermediate electrode covering one end of the heating element and one end of the overcoat covering the end of the intermediate electrode. the distance L ₁ from the predetermined portion of the intermediate electrode to the overcoat end, with respect to the distance L ₂ to the heating element end from a given portion of the intermediate electrode, that it is the L _1> L ₂ -300Myuemu A protective element characterized. The protective element according to claim 1, wherein L ₁ ≧ L ₂ is satisfied. The protective element according to claim 1 or 2, wherein a covering distance L3 of one end portion of the overcoat with respect to one end portion of the intermediate electrode is 0.6 mm or less. A predetermined portion of the intermediate electrode having a heating element, a fusible alloy piece and an intermediate electrode on one side of the substrate, one end of the heating element being connected to one end of the intermediate electrode, and a predetermined distance from the one end of the heating element the fusible alloy piece is joined, a protection element overcoat is applied onto the heating element, the heating element end protrudes from the overcoat end, the heating element end and over an intermediate electrode piece end has issued butt A protective element covering one end of the coat. 5. The overcoat is extended along at least a part of an electrode edge of a portion where the electrode connected to the heating element and another electrode face each other. 6. Protection element.

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