JP2020107429A - Heater device - Google Patents

Abstract

To provide a heater device which can secure a sufficient heating range with respect to a headlight light permeation cover, and can be attached following a surface shape of the light permeation cover.SOLUTION: In a first seat part 11 and a second seat part 12 which are partially connected to each other, a slit 18 is formed between the first seat part 11 and the second seat part 12, and the slit 18 is formed into a shape which is notched from the other side of a heater width direction DRx, being a shape extending to the heater width direction DRx. Therefore, even if a surface shape of a light permeation cover is, for example, a complicated curved face, the slit 18 permits a change of a relative positional relationship between the first seat part 11 and the second seat part 12 following the surface shape of the light permeation cover. By this constitution, a sufficient heating range of a heater device 10 can be secured with respect to the light permeation cover compared with the case that the slit 18 is not formed, and the heater device 10 can be pasted following the surface shape of the light permeation cover.SELECTED DRAWING: Figure 2

Description

The present invention relates to a heater device that is attached to a light transmission cover of a vehicle lamp and transmits light.

As this type of heater device, for example, the heater device described in Patent Document 1 has been conventionally known. The heater device described in Patent Document 1 is an electric heater that generates heat when energized. Then, this heater device is attached to, for example, a lens of a rear combination lamp of a truck, and melts ice and snow adhering to the front surface of the lens.

JP, 2008-108646, A

For example, there is a film-shaped heater device that generates heat for the purpose of melting the snow and snow adhering to the light transmission cover of the vehicle lamp, such as the heater device of Patent Document 1 above. Such a film-shaped heater device is fixed by being attached to the light transmission cover of the vehicular lamp.

Here, since the light transmission cover of the vehicular lamp constitutes a part of the outer shape of the vehicle, the light transmission cover is often configured with a complicated curved surface instead of a flat surface. When the film-shaped heater device is attached to the light transmission cover having the complicated curved surface, the heater device needs to be attached so as to follow the complicated curved surface of the light transmission cover.

However, in the case of a film-shaped heater device formed in a simple shape such as a simple rectangular shape, the heater device is poor in elasticity, so that it is attached following the complicated curved surface of the light transmission cover. There is a limit. Therefore, when the heater device is attached to the light transmission cover, the heater device may be wrinkled. Therefore, conventionally, the surface of the light transmission cover to which the heater device is attached has been limited to a flat surface or a substantially flat surface.

Further, if the heater device is made small, it is considered possible to attach the heater device to the complicated curved surface of the light transmissive cover while avoiding the occurrence of wrinkles. The range becomes too small, and the purpose of melting the snow and ice adhering to the light transmission cover cannot be achieved. As a result of a detailed study by the inventor, the above has been found out.

In view of the above points, an object of the present invention is to provide a heater device that can secure a sufficient heating range for a light transmission cover and that can be attached by following the surface shape of the light transmission cover.

In order to achieve the above object, the heater device according to claim 1,
A film-shaped heater device that is attached to a light transmission cover (701) that constitutes a part of a vehicular lamp (70) provided outside the vehicle cabin and that transmits light emitted from inside the vehicular lamp, and transmits the light. And
A first sheet portion (11) having a first heat generation region (111) that has a shape extending in one direction (DRx) and generates heat;
A second heat generating region (121) that is arranged side by side with respect to the first sheet portion on one side of the sheet portion arranging direction (DRy) orthogonal to the one direction and has a shape extending in the one direction and that generates heat is formed. A second sheet portion (12) having
A connecting sheet portion (14) which is arranged biased to one side in the one direction as compared with each of the first sheet portion and the second sheet portion and partially connects the first sheet portion and the second sheet portion. When,
A terminal installation part (16) provided with terminals (211, 221) electrically connected to a power supply for energizing the first heat generation region and the second heat generation region,
The first sheet portion and the second sheet portion are provided with a slit (18) cut from the other side opposite to the one side in the one direction and extended in the one direction. Formed between the part,
The slit is arranged on the other side of the one direction from the connecting sheet portion,
The terminal installation portion is arranged biased to the other side in the one direction as compared with the first sheet portion, and is connected to the first sheet portion.

With this configuration, since the slit is formed between the first sheet portion and the second sheet portion as described above, even if the surface shape of the light transmission cover is, for example, a complicated curved surface, the slit is The relative positional relationship between the first sheet portion and the second sheet portion is allowed to change following the surface shape of the light transmission cover. Therefore, as compared with the case where the slit is not provided, it is possible to secure a sufficient heating range of the heater device with respect to the light transmission cover and to attach the heater device by following the surface shape of the light transmission cover. ..

Then, as described above, the connecting sheet portion is arranged so as to be biased toward one side in the one direction as compared with the first sheet portion and the second sheet portion, respectively, and the terminal installation portion is provided with the first sheet portion. In comparison, it is arranged biased to the other side in the above-mentioned one direction and is connected to the first seat portion. Therefore, if attention is paid to the positional relationship among the terminal installation portion, the first heat generation area, and the connection sheet portion, the first heat generation area is located between the terminal installation portion and the connection sheet portion. Therefore, it is easy to simply configure the wiring path from the terminal installation portion to the connection sheet portion while supplying power to the first heat generation region.

The reference numerals in parentheses attached to the respective components and the like indicate an example of a correspondence relationship between the components and the like and specific components and the like described in the embodiments described later.

In 1st Embodiment, it is the figure which showed the state which the heater apparatus was affixed to the light transmission cover of the vehicle headlamp. In 1st Embodiment, it is the front view which looked at the single body of the heater apparatus before being adhere|attached on the light transmission cover from the opposite side to the attachment surface side with respect to the light transmission cover. It is the figure which looked at the heater device from the same direction as Drawing 2, and is a figure showing the 1st resistor and the 2nd resistor. It is sectional drawing which showed the IV-IV cross section of FIG. 2 typically. It is the figure which showed the state which the heater apparatus was affixed to the light transmission cover of the vehicle headlamp in the comparative example contrasted with 1st Embodiment.

Hereinafter, embodiments will be described with reference to the drawings. In the following embodiments including other embodiments to be described later, the same or equivalent portions are denoted by the same reference numerals in the drawings.

(First embodiment)
As shown in FIG. 1, the film-shaped heater device 10 of the present embodiment transmits light, and is attached to a light-transmitting cover 701 forming a part of a vehicle headlight 70. The headlight 70 is a type of vehicle lamp provided outside the vehicle interior, and the light transmission cover 701 is made of, for example, a transparent resin and transmits light emitted from the light source inside the headlight 70 to the outside of the vehicle. .. In the present embodiment, the light source in the headlight 70 is a light emitting diode.

In addition, in FIG. 1, in order to make FIG. 1 easy to understand, the outline of the heater device 10 is added to the photographic image. Further, each arrow DR1 and DR2 in FIG. 1 indicates the direction of the vehicle in which the heater device 10 is provided. That is, the arrow DR1 in FIG. 1 indicates the vehicle vertical direction DR1, and the arrow DR2 in FIG. 2 indicates the vehicle lateral direction DR2, that is, the vehicle width direction DR2. These directions DR1 and DR2 are directions intersecting with each other, or strictly speaking, directions orthogonal to each other.

FIG. 2 shows the heater device 10 before being attached to the light transmission cover 701. The heater device 10 shown in FIG. 2 is a film-shaped electric heater attached to the outside of the light transmission cover 701. For example, the heater device 10 receives power supply from a vehicle battery that is a power source, and the power supply to the heater device 10 is turned on/off by an occupant operation switch operated by an occupant.

When the heater device 10 is energized, the heater device 10 generates heat and melts the ice and snow adhering to the light transmission cover 701. Strictly speaking, the ice and snow attached to the light transmission cover 701 is ice and snow attached to the heater device 10 attached to the light transmission cover 701.

As shown in FIG. 2, the heater device 10 is in the form of a single film and includes a first sheet portion 11, a second sheet portion 12, a connecting sheet portion 14, and a terminal installation portion 16. Further, the heater device 10 includes two conductive patterns 21 and 22 that linearly extend over the entire first sheet portion 11, the second sheet portion 12, the connecting sheet portion 14, and the terminal installation portion 16. One of the two conductive patterns 21 and 22 is referred to as a first conductive pattern 21, and the other is referred to as a second conductive pattern 22. The conductive patterns 21 and 22 are made of, for example, a metal foil such as a copper foil. The conductive patterns 21 and 22 alone do not transmit light, but have a thin linear shape, so that the light emitted from the headlight 70 is heated by the heater device. It does not prevent 10 from penetrating.

The first sheet portion 11 and the second sheet portion 12 have a rectangular shape as a whole. The first sheet portion 11 has a rectangular shape extending in the heater width direction DRx as one direction. Therefore, the first sheet portion 11 has a pair of long sides 11a and 11b and a pair of short sides 11c and 11d as part of the outer shape of the first sheet portion 11. The long sides 11a and 11b extend in the heater width direction DRx, and the short sides 11c and 11d extend in the seat portion arranging direction DRy described later.

In addition, the first sheet portion 11 has a first heat generating area 111 that generates heat, and the first heat generating area 111 has a rectangular shape extending in the heater width direction DRx like the first sheet portion 11. ..

The second seat portion 12 is arranged side by side with respect to the first seat portion 11 on one side of the seat portion arrangement direction DRy orthogonal to the heater width direction DRx. The second seat portion 12 has the same shape as the first seat portion 11. That is, the second seat portion 12 also has a rectangular shape extending in the heater width direction DRx. Therefore, the second sheet portion 12 has a pair of long sides 12a and 12b and a pair of short sides 12c and 12d as part of the outer shape of the second sheet portion 12. The long sides 12a and 12b extend in the heater width direction DRx, and the short sides 12c and 12d extend in the seat portion arranging direction DRy.

In addition, the second sheet portion 12 has a second heat generating area 121 for generating heat, and the second heat generating area 121 has a rectangular shape extending in the heater width direction DRx like the second sheet portion 12. ..

The connecting sheet portion 14 is arranged between the first sheet portion 11 and the second sheet portion 12 in the sheet portion arranging direction DRy, and partially connects the first sheet portion 11 and the second sheet portion 12. Further, the connecting sheet portion 14 is arranged to be biased to one side of the heater width direction DRx as compared with the first sheet portion 11 and the second sheet portion 12, respectively. Specifically, the connecting sheet portion 14 is arranged at one end of the width direction range in which the entire first sheet portion 11 and the second sheet portion 12 occupy in the heater width direction DRx.

In addition, the first sheet portion 11 and the second sheet portion 12 form a slit 18 between the first sheet portion 11 and the second sheet portion 12. The slit 18 has a shape cut from the other side opposite to one side of the heater width direction DRx and extends in the heater width direction DRx, and is formed in the heater width direction DRx rather than the connecting sheet portion 14. Is located on the other side of.

For example, the connecting sheet portion 14 has a predetermined length larger than zero in the sheet portion arrangement direction DRy, and the slit 18 has a predetermined slit width larger than zero in the sheet portion arrangement direction DRy. That is, the first sheet portion 11 and the second sheet portion 12 are arranged apart from each other in the sheet portion arrangement direction DRy with the slit 18 interposed therebetween. In this embodiment, the predetermined slit width of the slit 18 is the same as the predetermined length of the connecting sheet portion 14.

The terminal installation part 16 has a pair of terminals 211 and 221 electrically connected to a power source (specifically, a vehicle battery) for energizing the first heat generating area 111 and the second heat generating area 121. doing. The first terminal 211 which is one of the pair of terminals 211 and 221 is included in the first conductive pattern 21, and the second terminal 221 which is the other of the pair of terminals 211 and 221 is included in the second conductive pattern 22. There is. The second terminal 221 is arranged on one side of the heater width direction DRx with respect to the first terminal 211. The pair of terminals 211 and 221 are exposed on the surface of the terminal installation portion 16, respectively.

The terminal installation portion 16 is connected to the first seat portion 11 and is arranged biased to the other side in the heater width direction DRx as compared with the first seat portion 11. Specifically, the terminal installation portion 16 is arranged at the other end of the width direction range occupied by the first sheet portion 11 in the heater width direction DRx.

Further, the terminal installation portion 16 is formed so as to extend from the first sheet portion 11 to the other side opposite to the one side in the sheet arrangement direction DRy.

As shown in FIGS. 2 and 3, the first heat generating region 111 is provided with a film-shaped first resistor 111a that is light-transmittable (transparently speaking, transparent), and the second heat generating region 121 is A film-shaped second resistor 121a capable of transmitting light is provided. The light-transmissive film shape is, to put it simply, a transparent film shape.

Further, the first resistor 111a and the second resistor 121a may be formed apart from each other, but in the present embodiment, the first resistor 111a and the second resistor 121a are connected to each other in the connecting sheet portion 14. linked. As a material for the first resistor 111a and the second resistor 121a, for example, indium tin oxide (abbreviated as ITO), carbon nanotube (abbreviated as CNT), Ag stack film, or the like can be adopted. In addition, in FIG. 3, the first resistor 111a and the second resistor 121a are shown by broken line hatching.

The first sheet portion 11 has a pair of first one-side electrode 212 and first other-side electrode 222. The first one-side electrode 212 and the first other-side electrode 222 respectively extend in the heater width direction DRx and are electrically connected to the first resistor 111a. The first one-side electrode 212 is included in the first conductive pattern 21, and is arranged on one side of the first heat generating region 111 in the sheet portion arrangement direction DRy. On the other hand, the first other-side electrode 222 is included in the second conductive pattern 22 and is arranged on the other side of the first heat generating region 111 in the sheet portion arrangement direction DRy.

The electrode arrangement of the second sheet portion 12 is also the same as the electrode arrangement of the first sheet portion 11 described above. That is, the second sheet portion 12 has a pair of second one-side electrode 223 and second other-side electrode 213. The second one-side electrode 223 and the second other-side electrode 213 respectively extend in the heater width direction DRx and are electrically connected to the second resistor 121a. The second one-side electrode 223 is included in the second conductive pattern 22 and is arranged on one side of the second heat generating region 121 in the sheet portion arrangement direction DRy. On the other hand, the second other-side electrode 213 is included in the first conductive pattern 21 and is arranged on the other side of the second heat generating region 121 in the sheet portion arrangement direction DRy.

As described above, since the first one side electrode 212 and the second other side electrode 213 are included in the first conductive pattern 21, they are electrically connected to the first terminal 211. Since the first other side electrode 222 and the second one side electrode 223 are included in the second conductive pattern 22, they are electrically connected to the second terminal 221.

Here, the cross-sectional structure of the heater device 10 will be described. In the heater device 10, for example, as shown in FIG. ) Are laminated and fixed to each other. FIG. 4 is a cross-sectional view of a portion of the first sheet portion 11, but the laminated structure of the second sheet portion 12 is similar to the laminated structure of the first sheet portion 11, and therefore is shown in FIG. The structure will be described.

In the cross section of FIG. 4, in the heater thickness direction DRt, the first resistor 111a is stacked on one side of the base sheet 101, and the second conductive pattern 22 is stacked on one side of the first resistor 111a. A cover sheet 102 is laminated on one side of the two conductive patterns 22. Further, in the heater thickness direction DRt, an adhesive layer 103 made of a film-like adhesive for adhering the heater device 10 to the light transmission cover 701 is laminated on the other side of the base material sheet 101.

The base sheet 101, the cover sheet 102, and the adhesive layer 103 are all transparent. The base sheet 101, the cover sheet 102, and the adhesive layer 103 are all spread over the entire heater device 10. However, the cover sheet 102 is formed on the terminals 211 and 221 in order to expose the terminals 211 and 221. Then it is partially hollowed out. The base sheet 101 and the cover sheet 102 are resin sheets such as PET.

As shown in FIGS. 2 and 3, in addition to the first terminal 211 and the second terminal 221, the terminal installation portion 16 has a pair of terminal connection portions 214 and 224 extending in the seat portion arrangement direction DRy. .. The first terminal connection portion 214, which is one of the pair of terminal connection portions 214 and 224, is included in the first conductive pattern 21, and the second terminal connection portion 224, which is the other of the pair of terminal connection portions 214 and 224, is the first. 2 included in the conductive pattern 22. The first terminal connecting portion 214 is arranged on the other side of the second terminal connecting portion 224 in the heater width direction DRx with a space.

The first terminal connection portion 214 extends from the terminal installation portion 16 into the first sheet portion 11, and electrically connects the first one-side electrode 212 and the first terminal 211. On the other hand, the second terminal connection portion 224 extends from the terminal installation portion 16 into the inside of the first sheet portion 11, and electrically connects the first other-side electrode 222 and the second terminal 221.

Further, the first terminal connecting portion 214 is arranged on the other side of the first resistor 111a in the heater width direction DRx, but the first terminal connecting portion 214 forms a non-conductor with the first resistor 111a. It is placed across. Specifically, the first terminal connecting portion 214 is arranged apart from the first resistor 111a on the other side in the heater width direction DRx. Therefore, the nonconductor between the first terminal connecting portion 214 and the first resistor 111a is, for example, the base sheet 101, the cover sheet 102, or the air. As a result, the first terminal connection portion 214 can be electrically conducted to the first resistor 111a via the first one-side electrode 212, but cannot be electrically conducted directly to the first resistor 111a. There is.

As shown in FIGS. 2 and 3, the first conductive pattern 21 of the heater device 10 includes a first inter-electrode connecting portion 215, and the second conductive pattern 22 includes a second inter-electrode connecting portion 225. The first inter-electrode connecting portion 215 and the second inter-electrode connecting portion 225 are formed so as to extend through the connecting sheet portion 14 in the sheet portion arrangement direction DRy. The first inter-electrode connecting section 215 is arranged on the other side of the second inter-electrode connecting section 225 in the heater width direction DRx with a space.

The first inter-electrode connecting portion 215 extends from the connecting sheet portion 14 into the first sheet portion 11, and also extends from the connecting sheet portion 14 into the second sheet portion 12. The first inter-electrode connecting portion 215 electrically connects the first one-side electrode 212 and the second other-side electrode 213. On the other hand, the second inter-electrode connecting portion 225 extends from the connecting sheet portion 14 into the first sheet portion 11 and also extends from the connecting sheet portion 14 into the second sheet portion 12. The second inter-electrode connecting portion 225 electrically connects the first other side electrode 222 and the second one side electrode 223.

In addition, the second inter-electrode connecting portion 225 is arranged on one side of the first resistor 111a and the second resistor 121a in the heater width direction DRx. However, the second inter-electrode connecting portion 225 is arranged with the non-conductor sandwiched between it and the first resistor 111a, and is also arranged with the non-conductor sandwiched between it and the second resistor 121a. Specifically, the second inter-electrode connecting portion 225 is arranged away from the first resistor 111a on one side in the heater width direction DRx, and is also separated from the second resistor 121a on one side in the heater width direction DRx. It is arranged.

Therefore, the non-conductor between the second inter-electrode connecting portion 225 and the first resistor 111a and the non-conductor between the second inter-electrode connecting portion 225 and the second resistor 121a are, for example, the base sheet 101. , Cover sheet 102, or air. Thereby, the second inter-electrode connecting portion 225 can be electrically conducted to the first resistor 111a via the first other-side electrode 222, but cannot be electrically conducted directly to the first resistor 111a. ing. The second inter-electrode connecting portion 225 is electrically conductive to the second resistor 121a via the second one-side electrode 223, but is not directly electrically conductive to the second resistor 121a. There is.

In the vehicle, the heater device 10 configured as described above is supplied with power from the power source by electrically connecting the first terminal 211 and the second terminal 221 to a power source such as a vehicle battery. At this time, the first resistor 111a between the first one-side electrode 212 and the first other-side electrode 222 and the second resistor 121a between the second one-side electrode 223 and the second other-side electrode 213 are Connected in parallel to the power supply. Therefore, the first resistor 111a and the second resistor 121a are respectively energized by the power supply from the power source, and thereby generate heat. That is, the first heat generation region 111 provided with the first resistor 111a and the second heat generation region 121 provided with the second resistor 121a generate heat.

As described above, according to the present embodiment, as shown in FIG. 2, the connecting sheet portion 14 partially connects the first sheet portion 11 and the second sheet portion 12. Then, the first sheet portion 11 and the second sheet portion 12 form a slit 18 between the first sheet portion 11 and the second sheet portion 12, and the slit 18 is cut from the other side in the heater width direction DRx. The shape is such that it is extended to the heater width direction DRx.

Therefore, even if the surface shape of the light transmission cover 701 (see FIG. 1) is, for example, a complicated curved surface, the slit 18 has a relative positional relationship between the first sheet portion 11 and the second sheet portion 12 that is the light transmission cover. It is allowed to change following the surface shape of 701. Therefore, as compared with the case where the slit 18 is not provided, a sufficient heating range of the heater device 10 is secured with respect to the light transmission cover 701, and the heater device 10 is attached so as to follow the surface shape of the light transmission cover 701. It is possible.

For example, FIG. 5 shows a state in which the heater device 90 of the comparative example in which the slit 18 is removed from the heater device 10 of the present embodiment is attached to the light transmission cover 701 of the headlight 70. As shown in portions A1 to A3 of FIG. 5, in the heater device 90 of the comparative example having no slit 18, wrinkles are generated in the heater device 90 in the state where the heater device 90 is attached to the light transmission cover 701.

On the other hand, in the heater device 10 of the present embodiment, as shown in FIG. 1, the heater device 10 does not have wrinkles in the state where the heater device 10 is attached to the light transmission cover 701. That is, in the heater device 10 of the present embodiment, as described above, the heater device 10 can be attached so as to follow the surface shape of the light transmission cover 701 formed of the curved surface. In short, the heater device 10 can be attached so that the heater device 10 follows the surface shape of the light transmission cover 701 without wrinkles.

Further, since the heater device 10 can be attached to the light transmission cover 701 without wrinkles, peeling from the wrinkles as a starting point is prevented and the heater device 10 attached to the light transmission cover 701 has a good appearance. It is possible to

It should be noted that in FIG. 1, the heater device 10 is arranged so as to extend over most of the range of the light transmission cover 701 that overlaps the light source in the headlight 70 and the reflection plate around the light source in front of the vehicle. ing.

The surface of the light transmission cover 701 of FIG. 1 is formed such that the radius of curvature showing the curve in the vehicle up-down direction DR1 is smaller than the radius of curvature showing the curve in the vehicle width direction DR2. Therefore, the heater device 10 is arranged so that the short sides 11c, 11d, 12c, 12d of the first and second seat portions 11, 12 are closer to the direction along the vehicle up-down direction DR1 than to the direction along the vehicle width direction DR2. Is attached to the light transmission cover 701. In short, the heater device 10 transmits light such that the short sides 11c, 11d, 12c, 12d of the first and second seat portions 11, 12 are oriented along the vehicle vertical direction DR1 or substantially along the vehicle vertical direction DR1. It is attached to the cover 701. In this way, it is preferable to determine the orientation of the heater device 10 according to the size of the radius of curvature of the surface of the light transmission cover 701 in order to avoid wrinkles from occurring in the heater device 10.

Further, according to the present embodiment, as shown in FIG. 2, the connecting sheet portion 14 is biased to one side in the heater width direction DRx as compared with each of the first sheet portion 11 and the second sheet portion 12. It is arranged. On the other hand, the terminal installation part 16 is arranged closer to the other side in the heater width direction DRx than the first seat part 11 and is connected to the first seat part 11. Therefore, paying attention to the positional relationship among the terminal installation part 16, the first heat generation area 111, and the connection sheet part 14, the first heat generation area 111 is located between the terminal installation part 16 and the connection sheet part 14. Become. Therefore, it is easy to easily configure the wiring path from the terminal installation portion 16 to the connection sheet portion 14 while supplying power to the first heat generation area 111.

Further, according to the present embodiment, as shown in FIGS. 2 and 3, the first heat generating region 111 is provided with a light-transmittable film-shaped first resistor 111a. The first sheet portion 11 has a first one-side electrode 212 and a first other-side electrode 222 that extend in the heater width direction DRx and are electrically connected to the first resistor 111a. The first one-side electrode 212 is arranged on one side of the first heat generation area 111 in the sheet part arrangement direction DRy, and the first other-side electrode 222 is arranged on the other side of the first heat generation area 111 in the sheet part arrangement direction DRy. It is arranged. Further, the second heat generating region 121 is provided with a light-transmitting film-shaped second resistor 121a, and the second sheet portion 12 extends in the heater width direction DRx and is electrically connected to the second resistor 121a. A second one-side electrode 223 and a second other-side electrode 213 which are connected to each other. The second one-side electrode 223 is arranged on one side of the second heat generation area 121 in the sheet portion arrangement direction DRy, and the second other-side electrode 213 is arranged on the other side of the second heat generation area 121 in the sheet portion arrangement direction DRy. It is arranged. Therefore, it is easy to generate heat with a uniform temperature distribution in the first and second heating regions 111 and 121 by the film-shaped first and second resistors 111a and 121a.

Further, the first one-side electrode 212 and the first other-side electrode 222 are arranged side by side in the short-side direction of the first heat-generating region 111 instead of in the longitudinal direction according to the above-described arrangement with respect to the first heat-generating region 111. Therefore, for example, as compared with the case where the first one-side electrode 212 and the first other-side electrode 222 are lined up in the longitudinal direction of the first heat generation region 111, the first one-side electrode 212 and the first other-side electrode 222 are opposite to each other. It is possible to reduce the electric resistance generated by the first resistor 111a between the two. From this, there is an advantage that it is easy to control the temperature of the heater device 10 even with a low power supply voltage.

In addition, according to the present embodiment, the second inter-electrode connecting portion 225 extends in the sheet arrangement direction DRy through the connecting sheet portion 14, and electrically connects the first other side electrode 222 and the second one side electrode 223. Connect to each other. The second inter-electrode connecting portion 225 is arranged so as to sandwich the non-conductor with the first resistor 111a and also sandwich the non-conductor with the second resistor 121a.

Therefore, it is possible to secure an energization path between the first other side electrode 222 and the second one side electrode 223. At the same time, direct conduction between the second inter-electrode connecting portion 225 and the first resistor 111a without the first other-side electrode 222 is prevented, and the first resistance in the first heat generating region 111 is prevented. It is possible to make the distribution of the current flowing through the body 111a uniform. The distribution of the current flowing through the second resistor 121a in the second heat generating region 121 can be made uniform as well. As a result, it is possible to suppress heat generation unevenness in each of the first heat generation region 111 and the second heat generation region 121.

Further, according to the present embodiment, the first terminal connecting portion 214 electrically connects the first one-side electrode 212 and the first terminal 211, and sandwiches the nonconductor between the first resistor 111a and the first resistor 111a. It is arranged. Therefore, it is possible to secure an energization path between the first terminal 211 and the first one-side electrode 212. At the same time, it is possible to prevent direct energization between the first terminal connection part 214 and the first resistor 111a without the first one-side electrode 212, and thus the first resistor in the first heating region 111. It is possible to make the distribution of the current flowing through 111a uniform. As a result, it is possible to suppress heat generation unevenness in the first heat generation region 111.

(Other embodiments)
(1) In the above-described embodiment, as shown in FIG. 1, the vehicle lamp to which the heater device 10 is attached is the headlight 70, but is not limited to this. The vehicle lamp to which the heater device 10 is attached may be, for example, a rear combination lamp. Further, the light source in the vehicle lamp may be a light emitting diode or a halogen lamp, but when the light source is a light emitting diode, the heat generation amount of the light source itself is smaller than that of a halogen lamp. The effect that the device 10 melts ice and snow becomes more effective.

(2) In the above embodiment, the light transmission cover 701 to which the heater device 10 is attached is made of transparent resin, but may be made of glass.

(3) In the above-described embodiment, as shown in FIG. 3, the first terminal connecting portion 214 is arranged apart from the first resistor 111a on the other side in the heater width direction DRx, but this is an example. .. When the first terminal connecting portion 214 is not arranged apart from the first resistor 111a, for example, a non-conductive film or sheet is provided between the first terminal connecting portion 214 and the first resistor 111a. You can intervene. By doing so, the first terminal connecting portion 214 is arranged so as to sandwich the non-conductor with the first resistor 111a.

(4) In the above-described embodiment, as shown in FIGS. 2 and 3, the first sheet portion 11 includes the first resistor 111a that generates heat when energized and the two first resistors 111a that are electrically connected to the first resistor 111a. Electrodes 212 and 222, which is an example.

For example, it can be considered that the first sheet portion 11 has a resistance electric wire that generates heat when energized and extends linearly, instead of the first resistor 111a and the two electrodes 212 and 222. In such a configuration in which the first sheet portion 11 has a resistance wire that generates heat, for example, the resistance wire has a thin line width that does not substantially impair the light transmittance of the first sheet portion 11. The resistance wire is arranged in a meandering manner in the first heat generating area 111 so that the first heat generating area 111 generates heat over the entire area. This also applies to the second sheet portion 12.

Even in the configuration in which such a resistance wire is provided, the wiring route from the terminal installation portion 16 to the connection sheet portion 14 is simply configured based on the positional relationship among the terminal installation portion 16, the first heat generation area 111, and the connection sheet portion 14. It is possible to obtain the effect that it is easy.

(5) In the above-described embodiment, as shown in FIG. 1, the heater device 10 is attached to the outer surface of the light transmission cover 701 of the headlight 70 exposed to the outside of the vehicle, but this is an example. For example, the heater device 10 may be attached to the inside of the light transmission cover 701.

(6) The present invention is not limited to the above-described embodiment, but can be modified in various ways. In addition, it goes without saying that, in the above-described embodiment, the elements constituting the embodiment are not necessarily essential unless explicitly stated as being essential or in principle apparently essential. ..

Further, in the above-mentioned embodiment, when numerical values such as the number of components of the embodiment, numerical values, amounts, ranges, etc. are mentioned, it is clearly limited to a specific number when explicitly stated as being essential. However, the number is not limited to the specific number, except in the case of Further, in the above-mentioned embodiment, when referring to materials, shapes, positional relationships, etc. of constituent elements, etc., unless otherwise specified and in principle limited to specific materials, shapes, positional relationships, etc. The material, shape, positional relationship, etc. are not limited.

(Summary)
According to the first aspect described in part or all of the above-described embodiment, in the film-shaped heater device, the connecting sheet portion is unidirectional as compared with the first sheet portion and the second sheet portion, respectively. The first sheet portion and the second sheet portion are partially connected to each other and are partially biased. Further, the terminal installation portion is provided with a terminal electrically connected to a power supply for energizing the first heat generation region and the second heat generation region. The first sheet portion and the second sheet portion have slits having a shape cut from the other side opposite to the one side in the one direction and extended in the one direction. The slit is formed in the space and is arranged on the other side in the one direction with respect to the connecting sheet portion. The terminal installation portion is arranged biased to the other side in the one direction as compared with the first sheet portion, and is connected to the first sheet portion.

Further, according to the second aspect, the terminal installation portion is formed so as to extend from the first sheet portion to the other side opposite to the one side in the sheet arrangement direction.

Further, according to a third aspect, a light-transmitting film-shaped resistor is provided in each of the first heat generating region and the second heat generating region, and the first sheet portion extends in the one direction, It has a first one-side electrode and a first other-side electrode electrically connected to the resistor in the heat generation region. The first one-side electrode is arranged on one side of the first heat generation area in the sheet arrangement direction, and the first other-side electrode is arranged on the other side of the first heat generation area in the sheet arrangement direction. The second sheet portion has a second one-side electrode and a second other-side electrode that extend in the one direction and are electrically connected to the resistor in the second heat generating region. The second one-side electrode Is arranged on one side of the second heat generation area in the sheet arrangement direction, and the second other-side electrode is arranged on the other side of the second heat generation area in the sheet arrangement direction. Therefore, it is easy to generate heat with a uniform temperature distribution in the first and second heating regions by the film-shaped resistor.

Further, the first one-side electrode and the first other-side electrode are arranged side by side in the short-side direction of the first heat-generating region instead of the longitudinal direction according to the above-described arrangement with respect to the first heat-generating region. Therefore, for example, as compared with the case where the first one-side electrode and the first other-side electrode are arranged side by side in the longitudinal direction of the first heat generation region, for example, a film-shaped film is formed between the first one-side electrode and the first other-side electrode. It is possible to reduce the electric resistance generated by the resistor. From this, there is an advantage that the temperature of the heater device can be easily controlled even with a low power supply voltage.

According to a fourth aspect, the heater device includes an inter-electrode connecting portion, and the inter-electrode connecting portion extends through the connecting sheet portion in the sheet portion side-by-side direction, and the first other side electrode and the second one side electrode are provided. The side electrode is electrically connected. The inter-electrode connecting portion is arranged so as to sandwich the nonconductor between the resistor in the first heat generating area and the resistor in the second heat generating area.

Therefore, it is possible to secure an energization path between the first other side electrode and the second one side electrode. At the same time, it is possible to prevent the current from flowing directly between the inter-electrode connecting portion and the resistor in the first heating area without passing through the first other-side electrode, and the current flowing through the resistor in the first heating area. Can be made uniform. The distribution of the current flowing through the resistor in the second heat generation region can be made uniform as well. As a result, it is possible to suppress heat generation unevenness in each of the first heat generation region and the second heat generation region.

Further, according to a fifth aspect, the terminal connecting portion electrically connects the first one-side electrode and the terminal, and is arranged with a non-conductor interposed between the first heating region and the resistor. .. Therefore, it is possible to secure an energization path between the terminal and the first one-side electrode. At the same time, it is prevented that current is directly applied between the terminal connection portion and the resistor in the first heat generation region without passing through the first one-side electrode, and the current flowing through the resistor in the first heat generation region is prevented. It is possible to make the distribution uniform. As a result, it is possible to suppress heat generation unevenness in the first heat generation region.

11 1st seat part 12 2nd seat part 14 connection seat part 16 terminal installation part 18 slit 70 headlight (vehicle lamp)
111 first heat generating area 121 second heat generating area 211, 221 terminal 701 light transmission cover

Claims (5)

A film-shaped heater that is attached to a light transmission cover (701) that constitutes a part of a vehicular lamp (70) provided outside the vehicle cabin and that transmits the light emitted from inside the vehicular lamp and that transmits the light. A device,
A first sheet portion (11) having a first heat generation region (111) that has a shape extending in one direction (DRx) and generates heat;
A second heat generating region (121) that is arranged side by side with respect to the first sheet portion on one side of the sheet portion arranging direction (DRy) orthogonal to the one direction, has a shape extending in the one direction, and generates heat. A second sheet portion (12) having
A connecting sheet that is arranged to be biased to one side in the one direction as compared with each of the first sheet portion and the second sheet portion, and partially connects the first sheet portion and the second sheet portion. Part (14),
A terminal installation part (16) provided with terminals (211, 221) electrically connected to a power supply for energizing the first heat generation region and the second heat generation region,
The first sheet portion and the second sheet portion have slits (18) cut from the other side opposite to the one side in the one direction and extending in the one direction. And the second sheet portion,
The slit is arranged on the other side of the one direction than the connecting sheet portion,
The heater device, wherein the terminal installation portion is arranged biased to the other side in the one direction as compared with the first seat portion, and is connected to the first seat portion. The heater device according to claim 1, wherein the terminal installation portion is formed so as to extend from the first sheet portion to the other side opposite to the one side in the sheet arrangement direction. Light-transmissive film-like resistors (111a, 121a) are provided in the first heat generation region and the second heat generation region, respectively.
The first sheet portion includes a first one-side electrode (212) and a first other-side electrode (222) that extend in the one direction and are electrically connected to the resistor (111a) in the first heat generating region. Have
The first one-side electrode is arranged on the one side of the first heat generating region in the sheet part arranging direction,
The first other side electrode is arranged on the other side of the first heat generating region in the sheet part arranging direction,
The second sheet portion includes a second one-side electrode (223) and a second other-side electrode (213) that extend in the one direction and are electrically connected to the resistor (121a) in the second heat generating region. Have
The second one-side electrode is arranged on the one side of the second heat generating region in the sheet portion arranging direction,
The heater device according to claim 1 or 2, wherein the second other-side electrode is arranged on the other side of the second heat-generating region in the sheet part alignment direction. An inter-electrode connecting part (225) that extends in the sheet part alignment direction through the connecting sheet part and electrically connects the first other side electrode and the second one side electrode,
The inter-electrode connecting portion is arranged with a nonconductor interposed between the resistor in the first heat generation area and the resistor in the second heat generation area. The heater device according to claim 3, wherein A terminal connecting portion (214) extending in the seat portion arranging direction,
A film-shaped resistor (111a) capable of transmitting light is provided in the first heat generation region,
The first sheet portion has a first one-side electrode (212) and a first other-side electrode (222) that extend in the one direction and are electrically connected to the resistor in the first heat generating region. ,
The first one-side electrode is arranged on the one side of the first heat generating region in the sheet part arranging direction,
The first other side electrode is arranged on the other side of the first heat generating region in the sheet part arranging direction,
The terminal connecting portion electrically connects the first one-side electrode and the terminal (211), and is arranged with a non-conductor interposed between the resistor in the first heat generating region. Item 3. A heater device according to item 2.