The present invention relates to a fuse-equipped hermetic terminal.
A hermetic terminal has been used which is configured to be fixable to a mounting hole provided in a hermetic container in order to supply a signal or power to an electric device contained in the hermetic container. For example, in a compressor used for an air conditioner, refrigerator, or the like, power is supplied from a power supply to a motor in a container of a motor unit via a hermetic terminal hermetically fixed to the container.
Since a compressor such as that in the air conditioner or refrigerator has a motor therein, electrically conductive particles resulting from wear of a sliding portion such as a bearing are gradually accumulated in refrigerant and refrigerator oil. When these electrically conductive particles are adhered to a surface of a glass insulatively sealing a metal stem and an electrode rod of the hermetic terminal, an insulation resistance between the metal stem and the electrode rod is decreased gradually, which may result in a short circuit in an extreme case.
When such a short circuit occurs between the metal stem and the electrode rod, overcurrent may flow to increase temperature and accordingly melt the sealing glass, with the result that the electrode rod may be removed from the metal stem and the oil in the compressor may leak to outside. In order to prevent such a phenomenon, a hermetic terminal with a fuse region has been conventionally used. The hermetic terminal has a conductive pin provided with a portion that generates heat when supplied with power. When overcurrent flows, the heat generating portion is melted and disconnected, thus interrupting supply of power to the motor.
For example, a hermetic terminal described in Patent Document 1 is provided with a fuse region constituted of a neck portion having a small cross sectional area at an axial intermediate portion of a conductive pin of the hermetic terminal. Since the conductive pin itself has a current fuse function, the fuse region is melted and disconnected when overcurrent is applied thereto, thereby interrupting supply of power. In this way, the motor is prevented from being burned out.
In Patent Document 2, a pin material is roll-formed to provide a fuse region in a conductive pin. By the roll forming, a flange is formed in the pin material, thereby forming a small-diameter groove that defines the fuse region.
However, in each of the conventional hermetic terminals with the fuse regions, a portion of the conductive pin is formed to have a small diameter, thereby forming the fuse region having a small conductive capacity. When overcurrent is applied, this fuse region is heated to be red hot due to resistance heating, is then melted, and is disconnected. Therefore, in each of the conventional hermetic terminals with the fuse regions, it takes a long time until the conductive pin, which is composed of a steel material or copper material, is heated to be red hot and is disconnected due to the overcurrent. Moreover, the melting/disconnection temperature is also high to be more than 1000° C. Moreover, the fuse region of the conductive pin may not be disconnected as intended. Actually, a portion of connection of the conductive pin with an interconnection may be disconnected first. Thus, the disconnection does not always take place at the same portion, disadvantageously.
Further, when it takes a certain time or more for the fuse to be melted and disconnected, the glass serving as the insulating sealing material near the fuse region may be melted first, with the result that the conductive pin may be removed due to refrigerant internal pressure. To address this, in the hermetic terminal of Patent Document 2, the flange is provided in the conductive pin to prevent the removal of the conductive pin.
In the hermetic terminal of Patent Document 3, a high melting point glass material is used for the insulating sealing material. This makes it difficult to melt the insulating sealing material. However, use of such a special high melting point glass material leads to increased material cost. Moreover, an operation temperature in the glass sealing step needs to be changed to a higher temperature. These are not necessarily preferable in terms of product cost and production energy efficiency.
PTD1: Japanese Patent Laying-Open No. 61-135074
PTD2: Japanese Patent Laying-Open No. 63-021774
PTD3: Japanese Patent Laying-Open No. 06-060928
An object of the present invention is to provide a fuse-equipped hermetic terminal with improved safety.
In accordance with a fuse-equipped hermetic terminal according to one embodiment of the present invention, the fuse-equipped hermetic terminal includes: a housing provided with a hollow portion and a pair of through holes located with the hollow portion being interposed therebetween; a conductive pin extending through the housing via the pair of through holes and the hollow portion; and a pair of insulating sealing materials that each hermetically seal a gap between the conductive pin and a corresponding one of the pair of through holes. The conductive pin includes an inner pin, an outer pin, and a fuse element that bridges between the inner pin and the outer pin and that is located in the hollow portion.
In the fuse-equipped hermetic terminal, the housing may include a first eyelet and a second eyelet, at least a portion of the hollow portion being provided in the first eyelet, the second eyelet being sealed with the first eyelet. The first eyelet may be provided with one of the pair of through holes, and the second eyelet may be provided with the other of the pair of through holes.
In the fuse-equipped hermetic terminal, a portion of the hollow portion may be provided in the first eyelet, and another portion of the hollow portion may be provided in the second eyelet.
In the fuse-equipped hermetic terminal, at least a portion of the conductive pin may be constituted of a composite metal member including a core member and a jacket member.
In the fuse-equipped hermetic terminal, the core member may be composed of a fusible metal material, and the fuse element of the conductive pin may be constituted of the core member exposed through the jacket member.
In the fuse-equipped hermetic terminal, electric resistances of the outer pin and the inner pin may be different from each other.
In the fuse-equipped hermetic terminal, center axes of the pair of through holes may be deviated from each other.
In the fuse-equipped hermetic terminal, the fuse element may be composed of a fusible metal material selected from a group consisting of a solder alloy, copper, a copper alloy, aluminum, an aluminum alloy, silver, and a silver alloy.
According to the fuse-equipped hermetic terminal according to one embodiment of the present invention, there can be provided a fuse-equipped hermetic terminal with improved safety.
A fuse-equipped hermetic terminal according to one embodiment of the present invention includes: a housing provided with a hollow portion and a pair of through holes located with the hollow portion being interposed therebetween; a conductive pin extending through the housing via the pair of through holes and the hollow portion; and a pair of insulating sealing materials that each hermetically seal a gap between the conductive pin and a corresponding one of the pair of through holes. Each conductive pin includes an inner pin, an outer pin, and a fuse element that bridges between the inner pin and the outer pin and that is located in the hollow portion.
For example, a hermetic terminal 10 shown in
Fuse element 17 is not limited particularly as long as fuse element 17 is composed of a fusible metal material. Suitable examples of fuse element 17 include a solder alloy, copper, a copper alloy, aluminum, an aluminum alloy, silver, a silver alloy, and the like. For each of first eyelet 13 and second eyelet 14, a Fe-based metal material is suitable, such as carbon steel, stainless steel, or a Fe—Ni alloy.
For each of outer pin 151 and inner pin 152 of the conductive pin, an alloy such as a Fe—Cr alloy or a Fe—Ni alloy is suitable. When outer pin 151 and inner pin 152 are respectively constituted of composite metal members including core members and jacket members 151b, 152b that cover core members 151a, 152a, it is suitable to employ copper for core members 151a, 152a, and employ a steel material, a Fe—Cr alloy, a Fe—Ni alloy, or the like for jacket members 151b, 152b.
Insulating sealing material 16, which hermetically seals the conductive pin in first eyelet 13 or second eyelet 14, is not limited particularly as long as insulating sealing material 16 is a heat-resistant insulating material. Suitable examples of insulating sealing material 16 include: glass materials such as soda lime glass, soda barium glass, and borosilicate glass; and thermosetting resins such as an epoxy resin.
In the fuse-equipped hermetic terminal, a conductive pin having a fuse element built therein may be employed. Specifically, each of outer pin 151 and inner pin 152 of the conductive pin is constituted of a core member composed of a fusible metal; and a jacket member that covers a surface thereof. The fuse element may be obtained by exposing the core member therethrough at a predetermined portion and this fuse element may be accommodated in the housing.
In the fuse-equipped hermetic terminal according to one embodiment, fuse element 17 provided in the conductive pin is provided inside the housing. Fuse element 17 is melted and disconnected in response to extraordinary overheating or overcurrent, thereby interrupting the power supply circuit immediately. Since fuse element 17 is immediately disconnected, insulating sealing material 16 that seals the conductive pin can be prevented from being melted and removed without using a high melting point glass for insulating sealing material 16. Since fuse element 17, which is operable to be melted and disconnected, is disposed in the housing, fuse element 17 can be retained with external air or moisture being prevented from entering. Moreover, the melted and disconnected portion can be limited to be in the housing, thereby providing safety.
Outer pin 151 and inner pin 152 both included in the conductive pin can have configurations different from each other. For example, the outer pin and the inner pin can have electric resistances different from each other. When the electric resistance value of the outer pin<the electric resistance value of the inner pin, an amount of heat due to supplied power at the inner pin 152 side can be always larger than that at the outer pin 151 side. Accordingly, insulating sealing material 16 can be melted and removed only at the inner pin 152 side. Even when the melting and removal takes place at the inner pin 152 side, hermeticity in the container having hermetic terminal 10 attached thereto is not compromised because hermetic terminal 10 has a double structure (double sealing structure). As a result, an interconnection portion is avoided from being removed out of the container and the terminal pin, refrigerant, and oils and fats are avoided from being pushed to outside due to internal pressure, thus providing safety.
In the present specification, the outer pin refers to a pin that is disposed at an outer side of the container to which the fuse-equipped hermetic terminal is attached and that is connected to an external device such as a power supply device. The inner pin refers to a pin connected to an internal device, such as a motor or a control device, disposed in the container to which the hermetic terminal is attached. It should be noted that the housing included in hermetic terminal 10 differs from the above-mentioned container.
As shown in
Hermetic terminal 10 includes first eyelet 13, second eyelet 14, the conductive pins, and insulating sealing materials 16. First eyelet 13 is provided with hollow portion 11 and three through holes 12a, and is composed of carbon steel. Second eyelet 14 is provided with three through holes 12b and is joined to first eyelet 13 to form the housing. Through holes 12a and through holes 12b are located with hollow portion 11 being interposed therebetween. The number of through holes 12a, 12b may be one or two, and may be more than or equal to four.
Each of the conductive pins includes: outer pin 151 extending through through hole 12a; and inner pin 152 extending through through hole 12b. The conductive pin extends to the inner and outer sides of the housing. Insulating sealing materials 16 hermetically seal outer pin 151 in first eyelet 13 and hermetically seal inner pin 152 in second eyelet 14. Insulating sealing material 16 is composed of borosilicate glass. Fuse element 17, which is composed of a fusible metal material, bridges between outer pin 151 and inner pin 152. Fuse element 17 is accommodated in the housing.
Hollow portion 11 is formed in each of first eyelet 13 and second eyelet 14 as shown in
The conductive pin is constituted of one pair of outer pin 151 sealed in first eyelet 13 and inner pin 152 sealed in second eyelet 14. Outer pin 151 and inner pin 152 are electrically connected via fuse element 17 disposed in the hermetic housing.
For outer pin 151 and inner pin 152, composite metal pins are used which respectively include: copper core members 151a, 152a and jacket members 151b, 152b composed of a Fe—Cr alloy. The diameter of the copper core of outer pin 151 sealed in first eyelet 13 is made thick, whereas the diameter of the copper core of inner pin 152 sealed in second eyelet 14 is made thin. This leads to the electric resistance value of the outer pin<the electric resistance value of the inner pin, whereby the amount of heat due to supplied power at the inner pin side becomes larger than that at the outer pin side. Accordingly, even if insulating sealing material 16 is melted, the timing of the melting of the insulating sealing material at the inner pin side always comes first. Accordingly, removal of the sealing can be kept in the case.
Outer pin 151 and inner pin 152 can have the same structure. Each of outer pin 151 and inner pin 152 can be constituted of a single metal member, rather than the composite metal member.
In the present embodiment, core members 151a, 152a can be composed of a material different from that of fuse element 17. Likewise, jacket members 151b, 152b can be composed of a material different from that of fuse element 17.
Even when insulating sealing material 16 is melted at the inner pin side, hermeticity in the container having hermetic terminal 10 attached thereto is not compromised because hermetic terminal 10 has a double structure (double sealing structure). Accordingly, an interconnection cord and the conductive pin can be avoided from being removed out of the container together with the refrigerant and oils and fats, thus providing safety. A terminal plate 18 for connection with an interconnection as shown in
A fuse-equipped hermetic terminal 20 of a second embodiment is a modification of fuse-equipped hermetic terminal 10 described above. The position of the center axis of through hole 12a of first eyelet 13 is deviated from the position of the center axis of through hole 12b of second eyelet 14, thereby preventing sealed outer pin 251 and inner pin 252 from hitting each other.
As shown in
Each of the conductive pins includes: an outer pin 251 extending through through hole 22a; and inner pin 252 extending through through hole 22b. The conductive pin extends to the inner and outer sides of the housing. Insulating sealing materials 26 hermetically seal outer pin 251 in first eyelet 23 and hermetically seal inner pin 252 in second eyelet 24. Insulating sealing material 26 is composed of soda barium glass. Fuse element 27, which is composed of a fusible metal material, bridges between outer pin 251 and inner pin 252. Fuse element 27 is accommodated in the housing.
Hollow portion 21 is formed in each of first eyelet 23 and second eyelet 24 as shown in
For outer pin 151 and inner pin 152, composite metal pins are used which include: copper core members 152a, 152b and jacket members 151b, 152b composed of a Fe—Cr alloy. The diameter of the copper core of outer pin 251 sealed in first eyelet 23 is made thick, whereas the diameter of the copper core of inner pin 252 sealed in second eyelet 24 is made thin. This leads to the electric resistance value of the outer pin<the electric resistance value of the inner pin, whereby the amount of heat due to supplied power at the inner pin side becomes larger than that at the outer pin side. Accordingly, even if insulating sealing material 26 is melted, the timing of the melting of the insulating sealing material at the inner pin side always comes first. Accordingly, removal of the sealing can be kept in the case.
The center axis of through hole 22a of first eyelet 23 is deviated from the center axis of through hole 22b of second eyelet 24 in the rotation direction of each of first eyelet 23 and second eyelet 24. The center axis of through hole 22a of first eyelet 23 may be deviated from the center axis of through hole 22b of second eyelet 24 in the radial direction of each of first eyelet 23 and second eyelet 24.
The axis of outer pin 251 extending through through hole 22a of first eyelet 23 is deviated from the axis of inner pin 252 extending through through hole 22b of second eyelet 24, whereby outer pin 251 does not overlap with inner pin 252 in the upward/downward direction. Specifically, through hole 22a of the first eyelet is deviated from through hole 22b of the second eyelet by 60° in the rotation direction. Accordingly, even when the melting and removal take place at the inner pin 252 side, inner pin 252, which is pushed up, is not brought into contact with outer pin 251. In this way, inner pin 252 and outer pin 251 can be prevented from being electrically connected to each other again.
Even when insulating sealing material 26 is melted at the inner pin side, hermeticity in the container having hermetic terminal 20 attached thereto is not compromised because hermetic terminal 20 has a double structure (double sealing structure). Accordingly, an interconnection cord and the conductive pin can be avoided from being removed out of the container together with the refrigerant and oils and fats, thus providing safety. A terminal plate 28 for connection with an interconnection as shown in
A fuse-equipped hermetic terminal 30 of a third embodiment employs a conductive pin having a fuse element built therein.
As shown in
Each of the conductive pins includes: outer pin 351 extending through through hole 32a; and inner pin 352 extending through through hole 32b. The conductive pin extends to the inner and outer sides of the housing. Insulating sealing materials 36 hermetically seal outer pin 351 in first eyelet 33 and hermetically seal inner pin 352 in second eyelet 34. Insulating sealing material 36 is composed of borosilicate glass. Each of outer pin 351 and inner pin 352 is a composite metal member including a copper core member 35a and a jacket member 35b composed of a Fe—Cr alloy. Copper core member 35a is exposed at a predetermined portion to provide a fuse element 37. Fuse element 37 is accommodated in the housing. Outer pin 351 and inner pin 352 are electrically connected via fuse element 37 disposed in the hermetic housing.
Hollow portion 31 is formed in each of first eyelet 33 and second eyelet 34 as shown in
A terminal plate 38 for connection with an interconnection as shown in
The embodiments disclosed herein are illustrative and non-restrictive in any respect. The scope of the present invention is defined by the terms of the claims, rather than the embodiments described above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
The fuse-equipped hermetic terminal according to the present invention is useful as a type of hermetic terminal for a large amount of current. Particularly, the fuse-equipped hermetic terminal according to the present invention is suitable as a hermetic terminal that supplies a signal and power to an electric device stored in a hermetic container. For example, the fuse-equipped hermetic terminal according to the present invention can be used for a hermetic terminal of a motor unit of a compressor such as one in a refrigerator or air conditioner.
10, 20, 30: hermetic terminal; 11, 21, 31: hollow portion; 12a, 12b, 22a, 22b, 32a, 32b: through hole; 151, 251, 351: outer pin; 13, 23, 33: first eyelet; 152, 252, 352: inner pin; 14, 24, 34: second eyelet; 151a, 152a, 251a, 252a, 351a, 352a: core member; 151b, 152b, 251b, 252b, 351b, 352b: jacket member; 16, 26, 36: insulating sealing material; 17, 27, 37: fuse element; 18, 28, 38: terminal plate.
Number | Date | Country | Kind |
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2015-134889 | Jul 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/069701 | 7/1/2016 | WO | 00 |