JP2017084783A - Heater unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heater unit which can improve heating efficiency or to which various added values can be given.SOLUTION: Disclosed is a heater unit 31 which comprises: a first substrate 11 made of a foaming body having a polymeric material; a first linear body 1; a second substrate 12 made of the foaming body having the polymeric material; and a second linear body 2. One of the first linear body 1 and the second linear body 2 has a heating element wire, and the other has the heating element wire and/or a detection element wire. The first substrate 11 and the second substrate 12 are laminated and fixed. The first linear body 1 is arranged and installed on the surface of the first substrate 11 side. The second linear body 2 is arranged and installed on the surface of the second substrate 12 side. The first linear body 1 and the second linear body 2 have a thermal fusion material in at least a part in the outer periphery. The thermal fusion material of the first linear body 1 and the thermal fusion material of the second linear body 2 are impregnated into a pore of the first foaming body 11 and the second foaming body 12.SELECTED DRAWING: Figure 2

Description

  The present invention relates to, for example, a heater unit used for various types of heating, and particularly relates to a heater unit that can improve heating efficiency or can provide various added values.

  Conventionally, especially in an automobile, a heater unit using resistance heating has been used as an aspect of a warming instrument in cold weather. For example, in a vehicle seat, it has been proposed to assemble a heater unit in the vehicle seat in order to warm the back and buttocks of a passenger such as a driver. The vehicle seat includes a seat frame as a base, a seat pad made of foamed urethane resin or the like that imparts cushioning properties, and a seat skin that covers them. The heater unit is installed between the seat pad and the seat skin (see, for example, Patent Documents 1 to 3). Moreover, in order to warm a driver | operator's hand in a steering wheel, attaching the heater unit to the wheel part of a steering wheel is proposed. The steering wheel is composed of a wheel portion, a spoke portion, and a boss portion, and the wheel portion is composed of a wheel core material and a covering material made of a synthetic resin, a textile product, leather, or the like. The heater unit is installed between the wheel core material and the covering material, and is connected to a lead wire that has passed through the spoke part and the boss part to supply power (for example, see Patent Documents 4 and 5).

  As such a heater unit installed on a vehicle seat or a steering wheel, for example, as shown in Patent Documents 1 to 5, a heater in which a cord-like heater is arranged in a predetermined pattern shape on a base material is known. ing. Here, as the base material, various foamed resin sheets, foamed rubber sheets, rubber sheets, nonwoven fabrics, woven fabrics, and the like are disclosed.

Japanese Patent No. 4202071: Clave JP 2011-229795 A: Clave JP, 2014-209444, A: Crave International Publication WO2014 / 104000 Publication: Toyoda Gosei, Krabe JP 2014-143175 A: Clave

  Here, in both the vehicle seat and the steering wheel, the heater unit is installed in the immediate vicinity of the occupant such as the driver, and comes into contact with the occupant with a predetermined pressure such as sitting or gripping. Therefore, if the thickness is generated only at the place where the cord-like heater is disposed, the occupant feels the unevenness and feels uncomfortable.

  For such a problem, in the heater unit (sheet heater) according to Patent Document 1, 30% or more of the outer circumference of the cord heater seems to be bonded to the base cloth so that the cord heater sinks into the base cloth. Is disclosed. In the heater unit (seat heater) according to Patent Document 2, the cord heater is disposed on the side where the gap of the base cloth is large, and the side where the gap is small is the seat skin side so that the occupant is less likely to feel the cord heater. Is disclosed. In the heater unit according to Patent Document 3, it is disclosed that the passenger is less likely to feel uncomfortable by making the heat-sealed portion of the outer periphery of the cord-shaped heater flat. In the heater units according to Patent Documents 4 and 5, the thickness of the base material where the cord-like heater is disposed is thin so as to follow the shape of the cord-like heater. It is disclosed that it is difficult to receive the feel of a cord heater.

  These can be used without problems at this stage. However, in the future, there is a demand for further improving heating efficiency and providing other added value while maintaining such a characteristic that the passenger does not feel uncomfortable. In particular, in terms of improving the heating efficiency, it is conceivable to increase the density of the predetermined heater pattern. However, in the structure of the conventional heater unit, the density of the pattern is limited from the viewpoint of the manufacturing method. As another added value, for example, a temperature sensor may be provided, or a pressure sensor or a capacitance sensor may be provided as a grip sensor or a seating sensor, but the heater unit is basically narrow. Since the sensor is disposed in the gap, there has been no technology that is sufficiently satisfactory for the arrangement of these sensors.

  The present invention has been made to solve such drawbacks of the prior art. The object of the present invention is to improve the heating efficiency or to provide various added values. It is in providing the heater unit which can do.

In order to achieve the above object, a heater unit according to the present invention includes a first base material made of a polymer material foam, a first linear body, and a second base material made of a polymer material foam. And a second linear body, wherein either one of the first linear body and the second linear body has a heating element wire and the other one generates heat. It has either or both of a strand and a sensing strand, the first base material and the second base material are laminated and fixed, and the first linear body is The second linear body is disposed on the surface of the heater unit on the second base material side, and the second linear body is disposed on the surface of the heater unit on the second base material side. 1 linear body and said 2nd linear body are provided with the heat sealing | fusion material in at least one part of outer periphery, and the heat sealing | fusion material of said 1st linear body and said 2nd Heat Chakuzai of Jo body is one that is impregnated into the pores of the first foam and the second foam.
Further, it is conceivable that the first linear body and the second linear body do not overlap.

According to the present invention, when both the first linear body and the second linear body have heating element wires, the heater pattern can be changed by arranging the first linear body and the second linear body. It can be set as the heater unit densified rather than the structure of this. In addition, if the second linear body has a detection strand for detecting temperature, pressure, capacitance, etc., a heater unit having various sensor functions such as temperature, gripping, or seating is obtained. Can do. Even such a heater unit can be handled in the same manner as the conventional one, with the overall dimensions, particularly the thickness in question, being almost the same as the conventional one.
Moreover, since the heat sealing material is impregnated in both the first base material and the second base material, the first base material and the second base material are firmly bonded. Therefore, it can prevent that a 1st base material and a 2nd base material isolate | separate.
In particular, if the non-porous portion of the second foam is directly in the pores of the first foam, the first foam and the second foam without using an adhesive or the like. Is sufficiently fixed directly. This eliminates the step of arranging an adhesive or the like, reduces costs, and improves productivity. In addition, the flexibility and stretchability originally provided in the foam are not hindered by the adhesive or the like, and a laminated body that takes advantage of the characteristics of the first foam and the second foam can be obtained. it can.
In addition, since the first base material and the second base material are laminated, these two base materials can have different characteristics by having different characteristics. .
Further, when the base material is composed of only one sheet, if the base material is cracked or torn, the crack or tear is enlarged and the whole material is torn. Here, if a plurality of base materials are used, even if cracks or tears occur in one base material, the expansion of the cracks or tears can be accommodated only by the base material and does not affect other base materials. . As a result, the entire heater unit can be prevented from being broken.

It is a top view which shows the structure of the heater unit by this invention. It is a partially cutaway top view which shows the structure of the heater unit by this invention. It is a partially transparent top view which shows the structure of the heater unit by this invention. It is sectional drawing which expands and shows typically the principal part of the heater unit by Embodiment 1 of this invention. It is sectional drawing which expands the principal part of the heater unit by Embodiment 1 of this invention further, and shows typically. It is a side view which cuts off the part of an example of the structure of an example of the linear body used by this invention. It is a side view which cuts off the part of an example of the structure of an example of the linear body used by this invention. It is a figure which shows the structure of the hot press type heater manufacturing apparatus used by this invention. It is a partial perspective view which shows a mode that a linear body is arrange | positioned in the predetermined pattern shape in the heater unit of this invention. It is a microscope picture which shows the cross section of the heater unit by Embodiment 1 of this invention. It is a top view which shows the structure of the other heater unit by this invention. It is a partially notched top view which shows the structure of the other heater unit by this invention. It is a partially transparent top view which shows the structure of the other heater unit by this invention.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  First, the configuration of the cord-like heater used as the first linear body 1 and the second linear body 2 in the first embodiment will be described. The cord-like heater in the first embodiment is configured as shown in FIG. First, on the outer periphery of the heater core 3 made of an aromatic polyamide fiber bundle having an outer diameter of about 0.2 mm, seven heating element wires 5a made of a tin copper alloy wire having a wire diameter of 0.08 mm are aligned, and the pitch is 1.00 mm. Then, a cord-shaped heater is formed by being spirally wound. The heating element wire 5a is covered with an insulating film 5b made of polyurethane with a thickness of about 0.005 mm. On the outer periphery, a polyethylene resin blended with a flame retardant as the heat sealing material 9 is extruded and coated with a thickness of 0.25 mm. The cord heater used as the first linear body 1 and the second linear body 2 has such a configuration, and its finished outer diameter is 0.9 mm.

Next, the structure of the 1st base material 11 and the 2nd base material 12 is demonstrated as a base material which arrange | positions the 1st linear body 1 and the 2nd linear body 2 which comprise the said structure. The first base material 11 and the second base material 12 in Embodiment 1 have a weight per unit volume of 0.04 g / cm ³ (based on JIS K7222), hardness 220N (based on JIS K6400-2), and thickness. It consists of a foamed polyurethane resin with a thickness of 4 mm.

  Next, while arrange | positioning the said 1st linear body 1 and the 2nd linear body 2 to the 1st base material 11 and the 2nd base material 12 in a predetermined pattern shape, the 1st base material 11 A configuration for bonding and fixing the second base member 12, the first linear body 1 and the second linear body 2 will be described. First, the first linear body 1 and the first base material 11 are temporarily fixed.

  FIG. 8 is a diagram showing a configuration of a hot press type heater manufacturing apparatus 13 for heating and pressurizing the first base material 11 on which the first linear body 1 is disposed. First, there is a hot press jig 15, and a plurality of locking mechanisms 17 are provided on the hot press jig 15. As shown in FIG. 9, the locking mechanism 17 includes a pin 19, and the pin 19 is inserted into a hole 21 drilled in the hot press jig 15 from below. A retaining member 23 whose tip is a needle is attached to the upper portion of the pin 19 so as to be movable in the axial direction, and is always urged upward by a coil spring 25. Then, as indicated by phantom lines in FIG. 9, the cord-like heater 1 is arranged in a predetermined pattern shape while the cord-like heater 1 is hooked on the retaining members 23 of the plurality of retaining mechanisms 17. Become.

  Returning to FIG. 8, a press hot plate 27 is disposed above the plurality of locking mechanisms 17 so as to be movable up and down. That is, the first linear body 1 is arranged in a predetermined pattern shape while being hooked on the retaining members 23 of the plurality of retaining mechanisms 17, and the first equipment 11 is placed thereon. In this state, the press hot plate 27 is lowered to apply heat and pressure to the first linear body 1 and the first base material 11. When the press hot plate 27 is lowered, it is designed to be heated and pressurized to the extent that the first linear body 1 and the first base material 11 are temporarily fixed. In the present embodiment, the first linear body 1 is arranged such that the distance between the lines in the first linear body 1 is 5.0 mm in the main part.

  In the same manner, the second linear body and the second base material are temporarily fixed.

  And the 2nd base material 12 to which the 2nd linear body 2 was temporarily fixed on the 1st base material 11 to which the 1st linear body 1 was temporarily fixed was not interposed via an adhesive agent etc. Repeat. At this time, the surface of the first substrate 11 on which the first linear body 1 is not temporarily fixed and the surface of the second substrate 2 on which the second linear body is not temporarily fixed are in contact with each other. Overlay on. In this state, the press hot plate 27 is lowered to heat and pressurize the first linear body 1, the first base material 11, the second linear body 2 and the second base material 12. It is preferable that at least the compression amount of the base material 10 is designed to be larger than the outer diameter of the cord-like heater 1. As a result, the first base material 11 and the second base material 12 are compressed and densified, and the heat sealing material 9 of the first linear body 1 and the second linear body 2 is melted. Then, the heat sealing material 9 is impregnated in the pores of the first base material 11 and the second base material 12, and the first linear body 1, the first base material 11, and the second linear body. 2 and the 2nd base material 12 will adhere | attach and fix. It should be noted that the retaining members 23 of the plurality of retaining mechanisms 17 move downward against the urging force of the coil spring 25 during heating and pressurization due to the lowering of the press hot plate 27. In the present embodiment, the distance between the first linear body 1 and the second linear body 2 is 2.5 mm, and the second substrate is placed on the first base material 11. The material 12 was piled up.

  By performing the above operation, a heater unit 31 as shown in FIGS. 1 to 5 can be obtained. 2 is a partially cutaway view in FIG. 1, and FIG. 3 is a view in which the first base material 11 and the second base material 12 are transmitted in FIG. . FIG. 4 is a cross-sectional view schematically showing the main part of FIG. 1 in an enlarged manner, and FIG. 5 is a cross-sectional view schematically showing in a further enlarged manner. In Embodiment 1, since the 1st base material 11 and the 2nd base material 12 will be compressed with the flat press hot plate 27, the 1st linear body 1 and the 2nd linear body About the location where 2 is arrange | positioned, it will press more strongly. Thereby, the location in which the 1st linear body 1 or the 2nd linear body 2 in the 1st base material 11 and the 2nd base material 12 is arrange | positioned is the 1st linear body 1 or the 2nd. This is a shape that follows the shape of the linear body 2 and is thinner than other portions. Further, the heat-bonding material 9 of the first linear body 1 and the second linear body 2 is also greatly deformed by heating and pressurization, and is in contact with the first base material 11 and the second base material 12. The thickness of the part not to be thinned becomes flat. As a result, the heater unit 31 has no unevenness at the location where the first linear body 1 and the second linear body 2 are disposed, and has a flat shape and maintains the shape of the heat sealing material 9. Thus, this flat shape is maintained. In addition, the heater unit 31 obtained in this way can improve the mechanical strength because the first base material 11 and the second base material 12 are compressed and have a high density. The heat sealing material 9 of the first linear body 1 and the second linear body 2 is impregnated in the pores of the first base material 11 and the second base material 12, and the cord-like heater 1 and first The base material 11, the second linear body, and the second base material 12 are firmly bonded and fixed together. In addition, the thickness of the heater unit obtained by this Embodiment is 1.00 mm, and the 1st base material 11 in the location in which the 1st linear body 1 or the 2nd linear body 2 was arrange | positioned. Or the minimum thickness of the 2nd base material 12 is 0.52 mm, and the 1st base material 11 or 2nd in the location where the 1st linear body 1 and the 2nd linear body 2 are not arrange | positioned. The thickness of the substrate 12 was 1.00 mm.

When the first linear body 1 and the second linear body 2 are heat-sealed, the first base material 11 and the second base material 12 are sufficiently heated and pressurized to achieve high compression. In this case, even if the adhesive layer is not used, even if the first linear body 1 and the second linear body 2 are not disposed, the first substrate 11 and the second substrate The material 12 can be directly fixed with a peel strength of 1 N or more. This is because, since the first base material 11 and the second base material 12 are made of a foam of a polymer material, the non-porous portion of the other foam enters the pores of the one foam, and the anchor effect By fixing two foams. As described above, in this embodiment, the weight per unit volume is 0.04 g / cm ³ (conforming to JIS K7222), the hardness is 220 N (conforming to JIS K6400-2), and the thickness is 4 mm. One base material 11 and second base material 12 are used. About these, it superimposes without using an adhesive layer, it is compressed by heating and pressurizing until the thickness becomes 1 mm, and after the heating and pressing, the first linear body 1 and the second linear body 2 are compressed. The weight per unit volume of a portion that does not exist is 0.32 g / cm ³ (based on JIS K7222). Thus, peel strength was measured with respect to the base material on which the first base material 11 and the second base material 12 were laminated. Peel strength is measured with a push-pull gauge. The base material on which the first base material 11 and the second base material 12 are laminated is cut out to 25 mm × 150 mm, a 50 mm portion is peeled in advance from the longitudinal end, and the end of the first base 11 is removed. Is fixed to the push-pull gauge, the end of the second base material 12 is gripped, and peeled off in a direction opposite to the push-pull gauge at a speed of 10 mm / s (peeling angle 180 degrees), resulting in a maximum load. The value obtained was taken as the peel strength. The peel strength between the first base material 11 and the second base material 12 in the heater unit 31 according to Embodiment 1 measured in this manner was 6.2 N, which was a value sufficient for practical use. . Moreover, when the state after peeling was confirmed, it was confirmed that the peeling was not due to interface peeling but due to material destruction, and from this point it was confirmed that sufficient adhesion was obtained. For reference, when the peel strength was measured in the same manner using a sample obtained by bonding the first base material 11 and the second base material 12 with a double-sided adhesive tape, the peel strength was 13.7 N. . In addition, the first linear body 1 and the second linear body 2 are not used, and the first base material 11 and the second base material 12 are simply heated and pressurized in the same manner as in the above embodiment. When the peel strength was measured in the same manner using a sample in which compression was performed and the first base material 11 and the second base material 12 were fixed, the peel strength was 5.0 N, and interfacial peeling was performed. It was.

  In FIG. 10, the SEM photograph of the principal part of the heater unit 31 by Embodiment 1 is shown. It is confirmed that the heat sealing material 9 of the first linear body 1 and the second linear body 2 is impregnated in the pores of the first base material 11 and the second base material 12. Further, the non-porous portion of the second base material 12 enters into the pores of the first base material 11, and the non-porous portion of the first base material 11 enters into the pores of the second base material 12, It is confirmed that the first base material 11 and the second base material 12 are fixed by the anchor effect.

  With respect to the heater unit 31 according to the first embodiment obtained as described above, both ends of the first linear body 1 and the second linear body 2 are drawn out and connected to the lead wire 35. This lead wire The cord heater 1, the temperature control device 39, and the connector (not shown) are connected by 35. The temperature control device is arranged on the cord heater 1 and controls the temperature of the heater unit by the heat generated by the cord heater 1. And it will be connected to the electric system which is not illustrated via the above-mentioned connector.

  As described above, since the two cord-shaped heaters of the first linear body 1 and the second linear body 2 are arranged, it is difficult in the process with only one conventional cord-shaped heater. It is possible to arrange the cord-like heaters with a high-density pattern. Therefore, it is possible to obtain a heater unit that is superior in heating efficiency than conventional ones. Here, about the 1st linear body 1 and the 2nd linear body 2, each one end is connected to a lead wire as mentioned above, and the other end is the 1st linear body 1 and a 2nd linear shape. It is also conceivable to connect the bodies 2 in series. When the first linear body 1 and the second linear body 2 are both cord-like heaters having a heating element wire, they may be connected in series or in parallel. It is also conceivable that these are connected to completely different circuits and heated by separate control.

  An adhesive layer (not shown) may be formed on the first base material 11 or the second base material 12 in order to bond the heater unit 31 and the object to be heated. The adhesive layer is formed by previously forming an adhesive layer made of only an adhesive on the release sheet, and transferring the adhesive layer from the release sheet to the surface of the first substrate 11 or the second substrate 12. It is preferable. As a result, the adhesive does not enter the first base material 11 or the second base material 12, and an adhesive layer is formed only on the surface of the first base material 11 or the second base material 12. It will be. In addition, when the heater unit 31 and the object to be heated are bonded, if the structure of the first embodiment is used, the side on which the person using the object to be touched does not have the first linear body 1 disposed. It is preferable to arrange the heater unit so that This is because unevenness due to the first linear body 1 is less likely to appear on the surface of the covering material 78. On the other hand, in order to improve the temperature rise characteristic, conversely, the heater unit is arranged so that the side on which the person who uses the object to be heated touches the surface on which the first linear body 1 is disposed. Can also be considered

  The heater unit 31 according to the first embodiment thus obtained was assembled to the heated object. The object to be heated includes a wheel part in which a cylindrical metal pipe having a diameter of 35 mm is formed in a circular shape having a diameter of 380 mm, and three spoke parts that are formed from the center of the circular shape toward the circumference and connected to the wheel part. Is. The heater unit is assembled to the wheel portion of the body to be heated. In the heater unit of the first embodiment, the assembling workability was good. This is because the first linear body 1, the first base material 11, the second linear body 2 and the second base material 12 are sufficiently fixed, for example, by extending the heater unit 31. This is because the first base material 11 and the second base material 12 were not separated even when the shapes were adapted, and could be installed without any problem. In particular, it was possible to easily install the heater unit 31 by adapting the shape to a portion where the curved surface is combined, such as a connecting portion of the wheel portion and the spoke portion. In addition, if the 1st base material 11 and the 2nd base material 12 isolate | separate, the shift | offset | difference of a heater unit will arise also in the case of actual use, and it will feel uncomfortable.

  In addition, the heater unit 31 according to the first embodiment obtained as described above has a sense of incongruity when assembled so that the side on which the first linear body 1 is disposed is the heated body side. Confirmed. For confirmation, 10 users hold the heated object to which the heater unit 31 is assembled, and alternately hold it 10 times with the left and right hands, and the first linear body 1 or the second line. An interview was conducted to find out if the irregularities due to the body 2 were felt. As a result, the number of users who answered that the embodiment was uncomfortable was zero.

  Moreover, about the heater unit 31 by the said Embodiment 1, the notch was formed only in the 1st base material 11, and it arrange | positioned to the tensile testing machine and performed the fracture test. Thereby, first, the notch became large in the form which crossed the 1st base material 11, and the 1st base material 11 was torn. In this state, the second substrate 12 was not affected at all, and the heater unit 31 as a whole did not break. After that, the tensile force was further applied, and the second base material 12 was also torn.

  Further, after energizing the heater unit 31 according to the first embodiment for 180 seconds in an atmosphere of 25 ° C., the maximum temperature, the average temperature, and the minimum temperature are measured by thermography for the measurement range of the central portion of the heater unit 31 of 150 mm × 150 mm. The difference between the highest temperature and the lowest temperature was determined. According to this, the maximum temperature was 36.5 ° C., the average temperature was 35.5 ° C., the minimum temperature was 33.9 ° C., and the difference between the maximum temperature and the minimum temperature was 2.6 ° C. On the other hand, in Embodiment 1 described above, a material that does not use the second linear body 2 and the second base material 12 (only the first linear body 1 and the first base material 11) is created. The voltage was adjusted so that the output would be the same as in the first embodiment, and the others were energized under the same conditions, and the maximum temperature, average temperature, and minimum temperature were measured, and the difference between the maximum temperature and the minimum temperature was determined. According to this, the maximum temperature was 37.4 ° C, the average temperature was 35.2 ° C, the minimum temperature was 33.4 ° C, and the difference between the maximum temperature and the minimum temperature was 4.0 ° C. That is, it was recognized that the heater unit 31 according to Embodiment 1 can perform more uniform heating.

  In addition, this invention is not limited to said embodiment. As the cord-like heater used as the first linear body 1 or the second linear body 2 heating element, any conventionally known cord-shaped heater can be used. For example, as described in Japanese Patent No. 4202071, a heating element configured by aligning heating element strands is wound around the outer periphery of a heater core, and an insulating layer made of FEP is formed on the outer periphery. Correspondingly, a cord-like heater in which a heat-sealing layer made of polyethylene is formed, a cord-like shape in which the heater core 3 has heat shrinkability and heat-meltability as disclosed in the specification of Japanese Patent Application No. 2007-158452. Heater, as disclosed in Japanese Patent Application No. 2007-158453, a cord-like heater composed of a heating element in which heating elements covered with an insulating film are aligned, disclosed in Japanese Patent Application Laid-Open No. 2007-134341 Even if a heating element is used, such as a cord-like heater composed of a copper solid solution and a copper-silver eutectic silver-filled copper alloy wire made of fibers. There. Moreover, the thing of a structure as shown in FIG. 6 is also considered. Specifically, first, seven heating element wires 5a made of a tin copper alloy wire having a strand diameter of 0.08 mm are arranged on the outer periphery of the heater core 3 made of an aromatic polyamide fiber bundle having an outer diameter of about 0.2 mm. The first linear body 1 or the second linear body 2 as a cord-shaped heater is formed by being spirally wound at a pitch of 1.00 mm. The heating element wire 5a is covered with an insulating film 5b made of polyurethane with a thickness of about 0.005 mm. The cord-like heater has such a configuration, and its finished outer diameter is 0.38 mm. In the above embodiment, a cord-like heater having a heat fusion layer 9 formed on the outer periphery is used. However, if the first base material 11 and the second base material 12 are fixed sufficiently and sufficiently, It is also conceivable to use a material on which the heat sealing material 9 is not formed. What is necessary is just to form the heat sealing | fusion material 9 in the outer periphery of the 1st linear body 1 or the 2nd linear body 2 when a stronger adhesion fixation is required. Further, the heating element is not limited to the cord heater as described above, and may be, for example, a linear element such as a simple resistance wire, a foil-like resistor, a so-called PTC heating element, or the like. Various types are conceivable. Of course, you may form a heat-fusion layer in the outer periphery of these heat generating elements.

  As the first linear body or the second linear body, a linear detection line may be considered in addition to the cord heater. As the linear detection line, in the cord heater as described above, a heating element wire may be replaced with a detection element wire. About this detection line, for example, a temperature detection line that measures a change in resistance value due to the temperature of the detection element, a temperature detection line that detects conduction through the detection element by melting an insulating material that melts at a predetermined temperature, A temperature detection line that melts and breaks the detection element at a predetermined temperature, a grip detection line that measures the change in capacitance of the detection element, a seating detection line, and a pressure detection that detects or measures the tension and displacement of the detection element A wire or a load detection wire can be considered. In the present invention, one of the first linear body and the second linear body has a heating element wire, and the other has either or both of a heating element wire and a detection element wire. Will be doing. Therefore, it is also conceivable that either one or both of the first linear body and the second linear body have both a heating element wire and a detection element wire. As a linear body having both a heating element wire and a detection element wire, for example, the outer periphery of the heating element wire is coated with an insulating material, and the detection element wire is wound around the outer periphery, or the heating element that is individually insulated One that can be used by aligning the wire and the detection wire. In the case of using a linear body having a detection element wire, the detection element line is usually not directly connected to the heating element wire but connected to a control circuit or the like as a separate circuit. In addition, it is also possible to give the exothermic element the function of the detection element by performing temperature compensation by a control circuit or the like.

  The foam constituting the first base material 11 and the second base material 12 is not limited to the foamed polyurethane resin. For example, various foams such as a foamed resin sheet and a foamed rubber sheet made of other materials can be used. Molecular foams are conceivable. In particular, those excellent in stretchability are preferable, and those whose hardness is adjusted so that the irregularities of the cord-like heater do not appear on the surface are preferable. Further, in order to adjust the hardness, there are methods such as adjusting the foaming rate, changing the state of bubbles to closed cells or open cells, and using a material having a hardness suitable for the purpose. In particular, open cells are preferred so that the non-porous portions of the other foam can sufficiently enter the pores of one foam. Materials include polyurethane resin, chloroprene rubber, silicone resin, silicone rubber, neoprene rubber, diene rubber, nitrile rubber, natural rubber, polyethylene resin, polypropylene resin, ethylene-vinyl acetate copolymer, various resins, rubber, What is necessary is just to select from thermoplastic elastomers. Moreover, as above-mentioned, although the 1st base material 11 and the 2nd base material 12 will be laminated | stacked, it is good also considering these as a different material, respectively. For example, the following can be considered. Regarding one foam, it is conceivable to select one having a high porosity. By making the foam on the side where the first linear body 1 or the second linear body is present on the surface of the heater unit have a high porosity, the linear body is more reliably contained in the foam. A flat heater unit 31 can be obtained. It is also conceivable that one of the foams has a high porosity and the foam is melt-filled with another resin to form a composite material. By bonding the heater unit 31 onto the heated body and injection molding urethane resin or the like thereon, a heated body in which the heater unit 31 is embedded can be obtained, but on the side where the heated body does not exist If the foam has a high porosity, injection molded urethane resin or the like is filled into the pores of the foam, and the heater unit 31 is securely fixed. Further, by stacking foams having different hardnesses, it is possible to make it difficult to feel the presence of the linear body when the user touches the heater unit 31 or a product incorporating the same. Also, foams with excellent flame retardancy, foams with high tensile strength, foams with excellent chemical resistance, foams with excellent heat resistance, foams with excellent withstand voltage characteristics, foams with electromagnetic shielding properties, low resilience By combining various foams, such as a foam having heat resistance, a foam excellent in low-temperature brittleness, and a foam having high thermal conductivity, the heater unit 31 provided with an additional function can be obtained. Also, if thin foams are laminated, when placing the linear body by thermal fusion, a process of applying another foam after placing the thin foam on the thin foam should be taken. It is possible to prevent poor fusion due to the heat insulation effect of the foam. Moreover, it is good also as a multilayered structure which laminated | stacked another foam. In this case, it is preferable that the pores of all the foams are impregnated with the heat sealing material 9.

Among the above foams, those having an average weight per unit volume of 0.32 g / cm ³ or more are preferable. More particularly, the weight per unit volume superimposing a plurality of 0.32 g / cm ³ less than the foam, it is preferable that the 0.32 g / cm ³ or more by heating and pressing. In particular, the weight per unit volume superimposing a plurality of 0.04 g / cm ³ or less of the foam, it is preferable that the 0.32 g / cm ³ or more by heating and pressing. As a result, the non-porous part of the other foam surely enters the pores of one foam, and the foams are firmly fixed directly. At this time, it is conceivable that a part of the foam that does not need to be fixed is intentionally not heated and pressed, or that part is weakened. About the part which did not perform such heat pressurization, and the part which weakened pressurization, it is not counted in the weight per average unit volume. The average weight per unit volume is defined by the portion that is substantially directly fixed.

  In the present invention, it is preferable that the first substrate 11 and the second substrate 12 are directly fixed with a peel strength of 1 N or more. The direct fixing indicates that the fixing is performed without any other member such as an adhesive interposed therebetween. Of course, it is not necessary to fix directly in all the portions where the first base material 11 and the second base material 12 are in contact with each other. It may be fixed directly with strength.

  In the above embodiment, no adhesive or the like is interposed between the first base material 11 and the second base material 12, but in order to securely bond and fix them, It is conceivable to form an adhesive layer between the first base material 11 and the second base material 12. Specifically, for example, an adhesive is applied to the first base material 11 and / or the second base material 12, and a heat fusion resin is provided between the first base material 11 and the second base material 12. It is also possible to arrange sheets. As the adhesive layer, not only a heat-sealing resin, but also various adhesive layers such as an adhesive layer made of a polymer acrylic pressure-sensitive adhesive and not using a tape base material, and an adhesive layer formed by forming an adhesive on both surfaces of a polypropylene film are used. Things can be used. FMVSS No. If it has the flame retardance which passes the combustion test of 302 automotive interior materials, the flame retardance of a heater unit improves and is preferable. Moreover, in order not to impair the stretchability of the heater unit 31, it is preferable that the adhesive layer is made of only an adhesive. Of course, as described above, if the first base material 11 and the second base material 12 are sufficiently and sufficiently fixed by compression by heating and pressurization, the use of such an adhesive is only auxiliary. As a matter of fact, the adhesive is partially used.

  Moreover, the 1st base material 11 and the 2nd base material 12 do not need to be the same shape, and can also consider it as a different shape according to a use condition. For example, in order to correspond to a heated portion having a step, the first base material 11 or the second base material 12 having a shape in which the portion is cut out in order to reduce the thickness of the base material only at the step portion. It can also be used. Also, by making one of the first base material 11 and the second base material 12 slightly smaller, the thickness gradually increases from the peripheral part of the heater unit 31 toward the central part. Become. Thereby, the level | step difference of the installation part of the heater unit 31 and a non-installation part can be relieve | moderated. In that case, it is more preferable to incline the peripheral portions of the first base material 11 and the second base material 12 so that the thickness gradually increases.

  Further, regarding the positional relationship between the first linear body and the second linear body, various selections can be made according to the purpose. In the case where both the first linear body and the second linear body have heating element wires, for example, the first linear body is arranged in a pattern that is excellent in immediate warming at the time of rising, and the second linear body It is also conceivable to arrange the linear bodies in a pattern that has excellent thermal uniformity during temperature equilibrium. In this case, it is preferable to reduce the portion where the first linear body and the second linear body overlap as much as possible. This is because the portion becomes thick due to the diameter of two linear bodies, and the two exothermic wires are positioned in the vicinity of the poles, which may cause overheating. On the other hand, when either the first linear body or the second linear body has a detection strand for detecting temperature, the first linear body and the second linear body have the same pattern. It is preferable to arrange so as to overlap. This is because the detection element wire for detecting the temperature is positioned closest to the heating element element, thereby enabling more direct temperature detection. However, if there is a portion where the first linear body and the second linear body overlap, the first linear body and the second linear body may be short-circuited in the portion due to external force. Therefore, as shown in FIGS. 11-13, it is preferable to set it as the structure which the pattern of the 1st linear body 1 and the pattern of the 2nd linear body 2 do not overlap.

  Further, not only the first linear body and the first base material, the second linear body and the second base material, but also the third linear body, the third base material, and the fourth line. It is also conceivable to laminate the state body and the fourth base material.

  According to the heater unit of the present invention, the heating efficiency can be improved, or various added values can be added. Such heater units include, for example, electric blankets, electric carpets, automobiles, motorcycles, ships, various transportation vehicles, various agricultural vehicles, various civil engineering heavy machinery and other seat heaters, steering heaters, heating toilet seats, anti-fogging, etc. Application to mirror heaters, cooking utensils, floor heating heaters, clothes heaters, and the like is also conceivable.

DESCRIPTION OF SYMBOLS 1 1st linear body 2 2nd linear body 9 Heat-fusion material 11 1st base material 12 2nd base material 31 Heater unit

Claims (2)

A heater unit comprising a first substrate made of a polymer material foam, a first linear body, a second substrate made of a polymer material foam, and a second linear body. There,
Either one of the first linear body and the second linear body has a heating element wire, and the other has either or both of a heating element wire and a detection element wire,
The first base material and the second base material are laminated and fixed,
The first linear body is disposed on the surface of the heater unit on the first base material side, and the second linear body is a surface of the heater unit on the second base material side. Arranged on the
The first linear body and the second linear body have a heat-sealing material on at least a part of the outer periphery,
A heater unit in which pores of the first foam and the second foam are impregnated with the heat seal material of the first linear body and the heat seal material of the second linear body. . The heater unit according to claim 1, wherein the first linear body and the second linear body do not overlap.