JP2016213118A - plug - Google Patents

Abstract

A plug capable of accurately detecting heat generation in any of a plurality of energizing pins is provided.
A plug according to the present invention includes a plurality of round bar-shaped energization pins (10) whose axial directions are parallel to each other, and a plurality of temperature detection elements (41) that respectively detect temperatures of the plurality of energization pins (10). And). Each of the plurality of energizing pins (10) has a plane (14) whose normal direction intersects the axial direction. The plurality of temperature detecting elements (41) face each other without contacting the flat surface (14) of the plurality of energizing pins (10).
[Selection] Figure 1

Description

  The present invention relates to a plug, and more particularly to a plug that detects heat generation at a plurality of energizing pins.

  Patent Document 1 discloses a plug including a pair of round pin-like plug pins and a thermistor that detects the temperature of the pair of plug pins. If the plug of patent document 1 is used, the heat_generation | fever in a pair of plug pin resulting from the contact failure of a plug and a receptacle can be detected.

JP 2014-38785 A

  In the plug of Patent Document 1, the position of the thermistor is far from the pair of plug pins, and heat generated by the pair of plug pins cannot be detected accurately.

  The problem to be solved by the present invention is to provide a plug capable of accurately detecting heat generated by a plurality of energizing pins.

  The plug according to the present invention includes a plurality of round bar-shaped energization pins whose axial directions are parallel to each other, and a plurality of temperature detection elements that respectively detect temperatures of the plurality of energization pins. Each of the plurality of energizing pins has a plane whose normal direction intersects the axial direction. The plurality of temperature detection elements face each other without contacting the flat surfaces of the plurality of energization pins.

  According to the present invention, heat generated by a plurality of energizing pins can be accurately detected.

It is sectional drawing of the principal part of the plug of Embodiment 1 which concerns on this invention. FIG. 5 is another cross-sectional view of the main part of the plug according to the first embodiment. FIG. 3 is an exploded perspective view of the plug according to the first embodiment. It is a front view of the plug of Embodiment 1. It is a side view of the plug of Embodiment 1. It is a perspective view of the plug of Embodiment 1. It is a figure which shows the positional relationship of the electricity supply pin and temperature detection element in the plug of Embodiment 1. FIG. 6 is another diagram showing the positional relationship between the energization pins and the temperature detection elements in the plug according to the first embodiment. FIG. 6 is another diagram showing the positional relationship between the energization pins and the temperature detection elements in the plug according to the first embodiment. It is a disassembled perspective view of the plug of Embodiment 2 which concerns on this invention. It is a figure which shows the positional relationship of the electricity supply pin and temperature detection element in the plug of Embodiment 2. FIG. 10 is another diagram showing the positional relationship between the energization pins and the temperature detection elements in the plug according to the second embodiment. FIG. 10 is another diagram showing the positional relationship between the energization pins and the temperature detection elements in the plug according to the second embodiment.

(Embodiment 1)
Hereinafter, the plug according to the first embodiment of the present invention will be described with reference to FIGS. 1 is a cross-sectional view taken along line AA in FIG. 4, and FIG. 2 is a cross-sectional view taken along line BB in FIG. However, in FIG. 2, the configuration of the plug is partially omitted.

  The plug of this embodiment is a plug that conforms to IEC60309. As shown in FIGS. 3 to 6, the plug of this embodiment includes a plurality (two in this embodiment) of energizing pins 10, one ground pin 20, a plug body 30, a temperature detection unit 40, Cable 50. Hereinafter, if necessary, one of the two energization pins 10 is referred to as a first energization pin 10A, and the other is referred to as a second energization pin 10B.

  As shown in FIG. 3, the temperature detection unit 40 includes a plurality (two in this embodiment) of temperature detection elements 41 that respectively detect the temperatures of the plurality of energization pins 10, and a holder that holds the plurality of temperature detection elements 41. 42. Hereinafter, one of the two temperature detection elements 41 is referred to as a first temperature detection element 41A and the other is referred to as a second temperature detection element 41B as necessary.

  The first temperature detection element 41A is disposed in the vicinity of the first energization pin 10A so as not to contact the first energization pin 10A in order to detect the temperature of the first energization pin 10A. The second temperature detecting element 41B is disposed in the vicinity of the second energizing pin 10B so as not to contact the second energizing pin 10B in order to detect the temperature of the second energizing pin 10B.

  The temperature detection element 41 includes a temperature sensing unit 411 and a pair of terminals (lead terminals) 412 and 413. The temperature sensing unit 411 is a part that detects the ambient temperature. The temperature sensing unit 411 has a flat plate shape and has a flat temperature detection surface 414. The temperature detection element 41 is, for example, a thermistor, and more specifically, a PTC thermistor. Therefore, the resistance value of the temperature sensing unit 411 changes according to the ambient temperature.

  The holder 42 is made of an electrically insulating resin. The holder 42 has a plate shape. The first temperature detection element 41A and the second temperature detection element 41B are attached to both surfaces of the holder 42, respectively. At this time, the temperature detection surfaces 414 of the temperature detection elements 41 </ b> A and 41 </ b> B are directed to the side opposite to the holder 42.

  Further, the terminal 413 of the first temperature detection element 41A and the terminal 413 of the second temperature detection element 41B are electrically connected to each other. That is, the first temperature detection element 41A and the second temperature detection element 41B are connected in series.

  As illustrated in FIG. 3, the cable 50 includes five electric wires 51 to 55 and a sheath 56 that covers the five electric wires 51 to 55. Five electric wires 51 to 55 are exposed from the sheath 56 at the first end of the cable 50, and the second end of the cable 50 is connected to an arbitrary device (for example, a plug, a receptacle, etc.).

  The five electric wires 51 to 55 are two (first and second) conducting wires 51 and 52, a ground wire 53, and two (first and second) signal wires 54 and 55. .

  The first and second conducting lines 51 and 52 are voltage lines, for example. The first and second energization wires 51 and 52 are electrically connected to the first and second energization pins 10A and 10B, respectively.

  The ground line 53 is electrically connected to the ground pin 20.

  The first and second signal lines 54 and 55 are electrically connected to the temperature detection unit 40. Specifically, the first signal line 54 is electrically connected to the terminal 412 of the first temperature detection element 41A, and the second signal line 55 is electrically connected to the terminal 412 of the second temperature detection element 41B. That is, a series circuit of the first temperature detection element 41A and the second temperature detection element 41B is connected between the first signal line 54 and the second signal line 55.

  As shown in FIGS. 3 and 7 to 9, the energization pin 10 is formed in a round bar shape from metal. That is, the energization pin 10 is a round pin. The energization pin 10 includes, for example, a contact 11, an electric wire connection portion 12, and a flange 13. The contact 11 has a round bar shape. The contact 11 is used for electrical connection with a receptacle corresponding to the plug of this embodiment. The flange 13 is formed at one end (rear end, right end in FIG. 7) of the contact 11. The flange 13 has a round bar shape and a diameter larger than that of the contact 11. The flange 13 is used for positioning the energizing pin 10. More specifically, the energizing pin 10 is positioned with respect to the plug body 30 by the flange 13. The wire connection portion 12 is formed on the opposite side of the flange 13 from the contact 11. The electric wire connection part 12 is formed in a long flat plate shape. The electric wire connection part 12 is used for connection with the conducting wire 51 or the conducting wire 52.

  The energizing pin 10 further has a flat surface 14 as shown in FIGS. The flat surface 14 is provided to transmit the heat generated by the energization pins 10 to the temperature detection element 41. The plane 14 is a plane whose normal direction intersects the axial direction of the energization pin 10 (orthogonal in the present embodiment). At least a part of the plane 14 is formed in the flange 13. In other words, the flat surface 14 is also formed on the flange 13 so that the temperature detecting element 41 can be disposed at a predetermined position with respect to the flat surface 14. More specifically, the flat surface 14 is formed over the flange 13 and the electric wire connecting portion 12. The plane 14 is larger than the temperature detection surface 414.

  For example, as shown in FIGS. 7 and 8, the flat surface 14 is larger than the temperature detection surface 414 in the first direction parallel to the axial direction of the energization pin 10 (the left-right direction in FIGS. 7 and 8). In other words, the dimension D10 of the plane 14 in the first direction is larger than the dimension D11 of the temperature detection surface 414 in the first direction. 8 and 9, in the second direction (vertical direction in FIGS. 8 and 9) perpendicular to the axial direction of the energizing pin 10 and the normal direction of the plane 14, the plane 14 is the temperature detection surface. Greater than 414. In other words, the dimension D20 of the plane 14 in the second direction is larger than the dimension D21 of the temperature detection surface 414 in the second direction. A dimension D20 of the plane 14 in the second direction is a minimum dimension in a portion of the plane 14 facing the temperature detection surface 414.

  The plurality of energizing pins 10 are arranged so that the axial directions are parallel to each other. In addition, each plane 14 of the plurality of energization pins 10 faces the center of the plurality of energization pins 10. In the present embodiment, each plane 14 of the two energization pins 10 is the center of the two energization pins 10 (in other words, between the two energization pins 10 in a plane orthogonal to the axial direction of the two energization pins 10. Point). In other words, the flat surfaces 14 of the two energization pins 10 face each other.

  As shown in FIG. 3, the ground pin 20 is formed in a round bar shape from metal. The ground pin 20 has a contact 21, an electric wire connection portion 22, a flange 23, and a flat surface 24, similarly to the energization pin 10. The ground pin 20 is generally larger than the energizing pin 10. The ground pin 20 is arranged so that the axial direction is parallel to the plurality of energizing pins 10.

  As shown in FIGS. 3 and 6, the plug main body 30 includes a first cover (front cover) 31, a body block 32, a second cover (rear cover) 33, and a shell 34. The first cover 31, the body block 32, the second cover 33, and the shell 34 are formed of a resin having electrical insulation.

  The first cover 31 includes a storage portion 311, a front wall 312, and a sleeve 313.

  The storage unit 311 has a cylindrical shape and has openings at both ends (front end and rear end). The storage unit 311 mainly stores the body block 32.

  The front wall 312 covers an opening at one end (front end) of the storage portion 311. As shown in FIG. 4, the front wall 312 has a plurality (two in this embodiment) of energizing pin insertion holes 314 and ground pin insertion holes 315. Hereinafter, if necessary, one of the two energization pin insertion holes 314 is referred to as a first energization pin insertion hole 314A, and the other is referred to as a second energization pin insertion hole 314B.

  The inner diameter of the energization pin insertion hole 314 is larger than the outer diameter of the contact 11 of the energization pin 10 and smaller than the outer diameter of the flange 13. The energizing pin 10 is accommodated in the accommodating portion 311 so that the contact 11 protrudes outside the accommodating portion 311 through the energizing pin insertion hole 314. The inner diameter of the ground pin insertion hole 315 is larger than the outer diameter of the contact 21 of the ground pin 20 and smaller than the outer diameter of the flange 23. The ground pin 20 is stored in the storage portion 311 so that the contact 21 protrudes outside the storage portion 311 through the ground pin insertion hole 315.

  The sleeve 313 is formed on the surface of the front wall 312 opposite to the storage portion 311 (that is, the front surface). The sleeve 313 has a cylindrical shape and collectively surrounds the two energization pin insertion holes 314 and the ground pin insertion hole 315.

  As shown in FIGS. 1 to 3, the body block 32 includes a case 321. The case 321 includes a front wall portion 322 and two side wall portions (wall portions) 323 that are parallel to each other. Each of the two side wall portions 323 has a flat outer surface (a surface facing the outside of the case 321) 3231 and an inner surface (a surface facing the inner side of the case 321) 3232. The case 321 is configured to accommodate the temperature detection unit 40. The case 321 has, for example, a rectangular box shape with one side opened. Hereinafter, one of the two side wall portions 323 is referred to as a first side wall portion 323A and the other is referred to as a second side wall portion 323B as necessary.

  The temperature detection unit 40 is accommodated in the case 321 of the body block 32 as shown in FIGS. The two temperature detection elements 41 of the temperature detection unit 40 are opposed to the two side wall portions 323, respectively. In particular, the temperature detection surface 414 of the temperature detection element 41 is in contact with the inner surface 3232 of the side wall portion 323.

  As shown in FIGS. 1 and 2, the body block 32 is housed in the housing portion 311 of the first cover 31 and is fixed to the front wall portion 312. For example, the body block 32 is fixed to the first cover 31 using two first screws 35 (see FIG. 3).

  When the body block 32 is stored in the storage portion 311 of the first cover 31, the front wall portion 322 faces the front wall 312 of the first cover 31. Accordingly, the flange 13 of the energization pin 10 and the flange 23 of the ground pin 20 are held between the front wall portion 322 and the front wall 312 of the first cover 31. Further, the two side wall portions 323 face the flat surfaces 14 of the two energization pins 10, respectively. Specifically, the outer surface 3231 of the side wall portion 323 is opposed to be parallel to the flat surface 14 of the energization pin 10. Here, the flat surface 14 of the energization pin 10 is not in contact with the side wall portion 323. However, the clearance between the flat surface 14 of the energizing pin 10 and the side wall portion 323 is set so that the flat surface 14 of the energizing pin 10 contacts the side wall portion 323 when the energizing pin 10 attempts to rotate around its axial direction. Is done. That is, the rotation of the energizing pin 10 is prevented when the flat surface 14 of the energizing pin 10 (10A, 10B) contacts the side wall portion 323 (323A, 323B).

  Note that the flat surface 24 of the ground pin 20 faces the bottom surface of the case 321 in parallel. Here, the flat surface 24 of the ground pin 20 is not in contact with the case 321. However, the gap between the flat surface 24 of the ground pin 20 and the case 321 is set so that the flat surface 24 of the ground pin 20 contacts the case 321 when the ground pin 20 is about to rotate about its axial direction. . That is, the rotation of the ground pin 20 is prevented when the flat surface 24 of the ground pin 20 contacts the case 321.

  In the plug of this embodiment, as shown in FIGS. 1 and 2, the two temperature detection elements 41A and 41B are opposed to the planes 14 and 14 of the two energization pins 10A and 10B, respectively. In particular, the temperature detection surfaces 414 and 414 of the two temperature detection elements 41A and 41B respectively face the planes 14 and 14 of the two energization pins 10A and 10B in parallel. The two side wall portions 323A and 323B are located between the planes 14 and 14 of the two energization pins 10A and 10B and the two temperature detection elements 41A and 41B, respectively.

  As shown in FIG. 3, the second cover 33 has a plate shape. The second cover 33 is attached to the rear end of the storage portion 311 of the first cover 31 so as to close the opening at the rear end of the storage portion 311. The second cover 33 has a shape that fits with the rear portion of the body block 32. For example, the second cover 33 is fixed to the first cover 31 using two second screws 36. The second cover 33 includes through holes 331, 332, 333, 334, and 335 through which the five electric wires 51, 52, 53, 54, and 55 of the cable 50 pass. The second cover 33 is formed integrally with the cable 50 by, for example, insert molding.

  As shown in FIG. 1, the shell 34 covers the storage portion 311 of the first cover 31, the second cover 33, and the first end of the cable 50. The shell 34 is cylindrical. The shell 34 is not a part prepared in advance, but a part formed by insert molding. Therefore, the shell 34 is not drawn in FIG.

  A method for assembling the plug of this embodiment will be briefly described. The following description is merely an example, and the method of assembling the plug of the present embodiment is not limited to the following example.

  First, the second cover 33 is formed integrally with the cable 50 by insert molding.

  Next, the cable 50 is connected. Specifically, the first conducting wire 51 is connected to the wire connecting portion 12 of the first conducting pin 10A. The second conducting wire 52 is connected to the wire connecting portion 12 of the first conducting pin 10B. The ground wire 53 is connected to the wire connection portion 22 of the ground pin 20. The first signal line 54 is connected to the terminal 412 of the first temperature detection element 41 </ b> A of the temperature detection unit 40. The second signal line 55 is connected to the terminal 412 of the second temperature detection element 41B of the temperature detection unit 40.

  Thereby, a series circuit of the first temperature detection element 41 </ b> A and the second temperature detection element 41 </ b> B is connected between the first signal line 54 and the second signal line 55.

  Next, the second cover 33 is fitted into the body block 32. At this time, the temperature detection unit 40 is housed in the case 321 of the body block 32. Further, the first energization pin 10A, the second energization pin 10B, and the ground pin 20 are disposed around the case 321 (see FIG. 2).

  Next, the first energizing pin 10 </ b> A, the second energizing pin 10 </ b> B, the ground pin 20, and the body block 32 are accommodated in the accommodating portion 311 of the first cover 31. At this time, the first energization pin 10A is accommodated in the accommodating portion 311 so that the contact 11 protrudes outside the accommodating portion 311 through the energizing pin insertion hole 314A. The second energization pin 10B is accommodated in the accommodating portion 311 so that the contact 11 protrudes outside the accommodating portion 311 through the energizing pin insertion hole 314B. The ground pin 20 is stored in the storage portion 311 so that the contact 21 protrudes outside the storage portion 311 through the ground pin insertion hole 315. The body block 32 is fixed to the first cover 31 using the first screws 35 and 35.

  Then, the second cover 33 is fixed to the first cover 31 using the second screws 36 and 36.

  Finally, the shell 34 is formed by insert molding.

  As described above, the plug of the present embodiment as shown in FIG. 6 is obtained. The plug of the present embodiment includes a plurality of round bar-shaped energization pins 10 whose axial directions are parallel to each other, and a plurality of temperature detection elements 41 that respectively detect the temperatures of the plurality of energization pins 10. Each of the plurality of energizing pins 10 has a plane 14 whose normal direction intersects the axial direction. The plurality of temperature detection elements 41 face the flat surfaces 14 of the plurality of energization pins 10, respectively.

(Embodiment 2)
Hereinafter, the plug according to the second embodiment of the present invention will be described with reference to FIGS.

  As shown in FIG. 10, the plug according to the present embodiment is different from the plug according to the first embodiment mainly in the shape of a plurality of (two in the present embodiment) current-carrying pins 10 and the shape of one ground pin 20. . Therefore, the description of the same configuration as that of the first embodiment in the plug of the present embodiment is omitted.

  The energization pin 10 includes a contact 11, an electric wire connection portion 12, a flange 13, and a flat surface 14 similar to those in the first embodiment. In this embodiment, as shown in FIGS. 11 to 13, the flat surface 14 is formed only on the wire connection portion 12. Instead, the flange 13 is smaller in thickness (dimension in the front-rear direction) than in the first embodiment. That is, in this embodiment, instead of forming a part of the flat surface 14 on the flange 13, the thickness of the flange 13 itself is reduced. In other words, the thickness of the flange 13 is reduced so that the temperature detecting element 41 can be disposed at a predetermined position with respect to the plane 14.

  Also in this embodiment, the flat surface 14 is larger than the temperature detection surface 414. For example, as shown in FIGS. 11 and 12, the plane 14 is larger than the temperature detection surface 414 in a first direction parallel to the axial direction of the energization pin 10 (the left-right direction in FIGS. 11 and 12). In other words, the dimension D10 of the plane 14 in the first direction is larger than the dimension D11 of the temperature detection surface 414 in the first direction. 12 and 13, in the second direction (vertical direction in FIGS. 12 and 13) perpendicular to the axial direction of the energization pin 10 and the normal direction of the plane 14, the plane 14 is a temperature detection surface. Greater than 414. In other words, the dimension D20 of the plane 14 in the second direction is larger than the dimension D21 of the temperature detection surface 414 in the second direction. A dimension D20 of the plane 14 in the second direction is a minimum dimension in a portion of the plane 14 facing the temperature detection surface 414.

  The energizing pin 10 has a second flat surface 131 for preventing rotation. The second plane 131 is formed on the flange 13 and faces the direction opposite to the plane 14. The second plane 131 is used to prevent the energization pin 10 from rotating. Specifically, in the present embodiment, the first cover 31 has one or more protrusions facing the second plane 131. For example, the second plane 131 of the energization pin 10 is disposed so as not to contact one or more protrusions. However, the gap between the second plane 131 of the energizing pin 10 and the one or more protrusions is such that when the energizing pin 10 is about to rotate around its axial direction, the one or more second planes 131 of the energizing pin 10 are one or more. It is set to come into contact with the protrusion. That is, when the second flat surface 131 of the energizing pin 10 contacts one or more protrusions, the energizing pin 10 is prevented from rotating.

  Moreover, in the plug of this embodiment, the rotation of the energizing pin 10 is prevented by the flat surface 14 of the energizing pin 10 coming into contact with the side wall portion 323. In other words, in the plug of the present embodiment, the energization pin 10 is prevented from rotating by the planes of the plane (first plane) 14 and the second plane 131 facing in opposite directions.

  Similarly to the first embodiment, the ground pin 20 includes a contact 21, an electric wire connection portion 22, a flange 23, and a flat surface 24. In the present embodiment, the flat surface 24 is formed only on the wire connection portion 22. Instead, the flange 23 has a smaller thickness (dimension in the front-rear direction) than that of the first embodiment. That is, in this embodiment, instead of forming a part of the flat surface 24 on the flange 23, the thickness of the flange 23 itself is reduced.

  The ground pin 20 has a second flat surface 231 for preventing rotation. The second plane 231 is formed on the flange 23 and faces the direction opposite to the plane 24. The second plane 231 is used to prevent the ground pin 20 from rotating. Specifically, in the present embodiment, the first cover 31 has one or more protrusions (second protrusions) that face the second plane 231. That is, the rotation of the ground pin 20 is prevented by the second flat surface 231 of the ground pin 20 coming into contact with one or more protrusions (second protrusions).

  Further, in the plug of the present embodiment, the ground pin 20 is prevented from rotating because the flat surface 24 of the ground pin 20 contacts the case 321. That is, in the plug of the present embodiment, the ground pin 20 is prevented from rotating by the planes of the plane (first plane) 24 and the second plane 231 facing in opposite directions.

  Similar to the plug of the first embodiment, the plug of the present embodiment described above has a plurality of round bar-shaped energization pins 10 whose axial directions are parallel to each other and a plurality of temperature detections that respectively detect the temperatures of the plurality of energization pins 10. And an element 41. Each of the plurality of energizing pins 10 has a plane 14 whose normal direction intersects the axial direction. The plurality of temperature detection elements 41 face the flat surfaces 14 of the plurality of energization pins 10, respectively. However, in this embodiment, each of the plurality of energizing pins 10 includes a round bar-shaped contact 11, a flange 13 formed at one end of the contact 11, and a wire connection formed on the opposite side of the contact 11 of the flange 13. Unit 12. In each of the plurality of energizing pins 10, the flat surface 14 is formed only on the electric wire connecting portion 12.

  In addition, you may provide the 2nd plane 131 in this embodiment in the electricity supply pin 10 of Embodiment 1. FIG. Similarly, the second plane 241 in the present embodiment may be provided on the ground pin 20 of the first embodiment.

(Another embodiment)
In the plug of another embodiment according to the present invention, the plane (14) of the energization pin (10) may be substantially the same size as the temperature detection surface (414) of the temperature detection element (41). Further, the plane (14) may be smaller than the temperature detection surface (414) of the temperature detection element (41) as long as heat generation can be detected with high accuracy. For example, referring to FIGS. 7 and 8, the dimension D10 of the plane 14 in the first direction may be substantially the same as the dimension D11 of the temperature detection surface 414 in the first direction. Similarly, referring to FIGS. 8 and 9, the dimension D20 of the plane 14 in the second direction may be substantially the same as the dimension D21 of the temperature detection surface 414 in the second direction.

  In the plug of another embodiment according to the present invention, all of the plane (14) may be formed on the flange (13) in each of the plurality of energizing pins (10). A plane (14) may be formed on the entire flange (13) in the axial direction of the energization pin (10).

  The plug of another embodiment according to the present invention may include three or more energization pins (10) and one ground pin (20). Moreover, the several electricity supply pin (10) may contain the neutral pin. Also in this case, each plane (14) of the plurality of energization pins (10) can be arranged so as to face the center of the plurality of energization pins (10). For example, when the number of energization pins (10) is three, the plane (14) of each of the three energization pins (10) is the center of the three energization pins (10) (in other words, the three energization pins (10). ) Are arranged so as to face the center of a polygon having three current-carrying pins (10) as apexes in a plane perpendicular to the axial direction. That is, when the number of the energization pins (10) is three or more, the centers of the plurality of energization pins (10) are the plurality of energization pins (10) in a plane orthogonal to the axial direction of the plurality of energization pins (10). The center of the polygon as the vertex.

  In the plug of another embodiment according to the present invention, each plane (14) of the plurality of energization pins (10) may face the same direction, and is opposite to the center of the plurality of energization pins (10). You may turn to the side.

  The plug according to another embodiment of the present invention may not include the cable (50). In this case, the plug may include a terminal block to which the cable (50) is detachably connected.

  The plug according to another embodiment of the present invention may not include the shell (34).

  In the plug according to another embodiment of the present invention, the plug body (30) may be a stationary type.

  In another embodiment of the plug according to the present invention, the temperature sensing element (41) may be an NTC thermistor. In short, the temperature sensing element (41) is not particularly limited.

  The plug according to the present invention is not necessarily a plug that conforms to IEC60309. For example, the plug according to the present invention may be a plug that conforms to standards other than IEC60309 (CEE7 / 7, CEE7 / 16, CEE7 / 17, BS546, etc.). In short, the present invention is applicable to a plug having at least two round bar-like pins. The number of electric wires of the cable (50), the number of energizing pins (10), the presence / absence of a ground pin (20), and the arrangement of pins (energizing pins and ground pins) are also changed according to the standard.

(Mode of the present invention)
As is clear from the above embodiments, the plug of the first embodiment according to the present invention includes a plurality of round bar-shaped energization pins (10) whose axial directions are parallel to each other, and the temperatures of the plurality of energization pins (10). And a plurality of temperature detection elements (41) for detecting each of the above. Each of the plurality of energizing pins (10) has a plane (14) whose normal direction intersects the axial direction. The plurality of temperature detecting elements (41) face each other without contacting the flat surface (14) of the plurality of energizing pins (10).

  According to the plug of the first embodiment, since the plurality of temperature detecting elements (41) for detecting the temperatures of the plurality of energizing pins (10) are provided, one temperature detecting element is provided for the plurality of energizing pins (10). Compared with the case where there is only one, it is possible to accurately detect the heat generated by the plurality of energizing pins (10). Further, a plane (14) is formed on each of the plurality of energization pins (10), and the plurality of temperature detection elements (41) are opposed to the plane (14) instead of the curved surface portion of the plurality of energization pins (10). Yes. Therefore, the amount of heat transferred from the energizing pin (10) to the temperature detecting element (41) can be increased. Therefore, the heat generation at the plurality of energizing pins (10) can be detected with higher accuracy.

  The plug of the 2nd form which concerns on this invention is implement | achieved by the combination with a 1st form. In the second embodiment, each of the plurality of temperature detection elements (41) has a flat temperature detection surface (414). The temperature detection surfaces (414) of the plurality of temperature detection elements (41) respectively face the plane (14) of the plurality of pins in parallel.

  According to the plug of the 2nd form, since the quantity of the heat transmitted from the electricity supply pin (10) to the temperature detection element (41) can be increased, the detection accuracy of the heat_generation | fever in an electricity supply pin (10) improves.

  The plug of the 3rd form which concerns on this invention is implement | achieved by the combination with a 2nd form. In the third embodiment, in each of the plurality of energization pins (10), the normal direction of the plane (14) is orthogonal to the axial direction.

  According to the plug of the 3rd form, since the quantity of the heat transmitted from the electricity supply pin (10) to the temperature detection element (41) can be increased, the detection accuracy of the heat_generation | fever in an electricity supply pin (10) improves.

  The plug of the 4th form which concerns on this invention is implement | achieved by the combination with a 2nd or 3rd form. In the fourth embodiment, in each of the plurality of energizing pins (10), the plane (14) is larger than the temperature detection surface (414) facing the plane (14).

  According to the plug of the 4th form, since the quantity of the heat transmitted from the energization pin (10) to the temperature detection element (41) can be increased, the detection accuracy of heat generation at the energization pin (10) is improved.

  The plug of the 5th form which concerns on this invention is implement | achieved by the combination with any one of the 1st-4th form. In the fifth embodiment, each of the plurality of energizing pins (10) includes a round bar-shaped contact (11), a flange (13) formed at one end of the contact (11), and the flange (13). A wire connection portion (12) formed on the opposite side of the contact (11). In each of the plurality of energizing pins (10), at least a part of the plane (14) is formed on the flange (13).

  According to the plug of the fifth mode, since at least a part of the plane (14) is formed on the flange (13), the temperature detecting element (41) can be brought closer to the contact (11). Generally, heat generation at the energization pin (10) occurs at the contact (11). Therefore, the detection accuracy of heat generation at the energization pin (10) is improved.

  The plug of the 6th form which concerns on this invention is implement | achieved by the combination with any one of the 1st-4th form. In the sixth embodiment, each of the plurality of energizing pins (10) includes a round bar-shaped contact (11), a flange (13) formed at one end of the contact (11), and the flange (13). A wire connection portion (12) formed on the opposite side of the contact (11). In each of the plurality of current-carrying pins (10), the flat surface (14) is formed only in the electric wire connection portion (12).

  According to the plug of the sixth embodiment, since the flat surface (14) is formed only on the electric wire connecting portion (12), the thickness of the flange (13) is reduced, so that the temperature detecting element (41) is more contacted. (11) can be approached. Generally, heat generation at the energization pin (10) occurs at the contact (11). Therefore, the detection accuracy of heat generation at the energization pin (10) is improved.

  The plug of the 7th form which concerns on this invention is implement | achieved by the combination with any one of the 1st-6th form. In the seventh embodiment, the plane (14) of each of the plurality of energization pins (10) faces the center of the plurality of energization pins (10).

  According to the plug of the seventh embodiment, since the plurality of temperature detecting elements (41) are located in the space between the plurality of energizing pins (10), the size can be reduced.

  The plug of the 8th form which concerns on this invention is implement | achieved by the combination with any one of the 1st-7th form. In the seventh embodiment, the plug further includes a plurality of wall portions (323) having electrical insulation. The plurality of wall portions (323) are respectively positioned between the plane (14) of the plurality of energizing pins (10) and the plurality of temperature detection elements (41).

  According to the plug of the eighth embodiment, the energization pin (10) and the temperature detection element (41) can be reliably electrically insulated. In general, since solids are more likely to transfer heat than gases such as air, the wall (323) makes it easier for heat to be transferred from the energizing pin (10) to the temperature detection element (41). Therefore, the detection accuracy of heat generation at the energization pin (10) is improved.

  The plug of the ninth form according to the present invention is realized by a combination with the eighth form. In the ninth embodiment, the plurality of wall portions (323) prevent the plurality of energization pins (10) from rotating by contacting the flat surfaces (14) of the plurality of energization pins (10), respectively.

  According to the plug of the ninth embodiment, the wall portion (323) for electrically insulating the energizing pin (10) and the temperature detecting element (41) can be used as a member for preventing the energizing pin (10) from rotating. Function. Therefore, it is not necessary to newly provide a configuration for preventing the energization pin (10) from rotating, and thus the manufacturing cost is reduced.

DESCRIPTION OF SYMBOLS 10 Current supply pin 11 Contact 12 Electric wire connection part 13 Flange 14 Plane 323 Wall part 41 Temperature detection element 414 Temperature detection surface

Claims (9)

A plurality of round bar-shaped energization pins whose axial directions are parallel to each other;
A plurality of temperature detecting elements for detecting temperatures of the plurality of energizing pins, respectively;
With
Each of the plurality of energizing pins has a plane in which the normal direction intersects the axial direction,
The plurality of temperature detection elements face each other without contacting the flat surfaces of the plurality of energization pins,
Plug characterized by that. Each of the plurality of temperature detection elements has a flat temperature detection surface,
The temperature detection surfaces of the plurality of temperature detection elements respectively face the planes of the plurality of pins in parallel.
The plug according to claim 1. In each of the plurality of energizing pins, the normal direction of the plane is orthogonal to the axial direction.
The plug according to claim 2. In each of the plurality of energization pins, the plane is larger than the temperature detection surface facing the plane.
The plug according to claim 2 or 3. Each of the plurality of energizing pins is
A round bar-shaped contact,
A flange formed at one end of the contact;
A wire connecting portion formed on the opposite side of the flange from the contact;
With
In each of the plurality of energizing pins, at least a part of the plane is formed on the flange.
The plug according to any one of claims 1 to 4. Each of the plurality of energizing pins is
A round bar-shaped contact,
A flange formed at one end of the contact;
A wire connecting portion formed on the opposite side of the flange from the contact;
With
In each of the plurality of current-carrying pins, the plane is formed only at the wire connection portion.
The plug according to any one of claims 1 to 4. Each of the planes of the plurality of energization pins faces the center of the plurality of energization pins,
The plug according to any one of claims 1 to 6. A plurality of walls having electrical insulation properties;
The plurality of wall portions are respectively positioned between the planes of the plurality of energizing pins and the plurality of temperature detection elements.
The plug according to any one of claims 1 to 7. The plurality of wall portions prevent rotation of the plurality of energization pins by respectively contacting the planes of the plurality of energization pins.
The plug according to claim 8.

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