JP6513522B2 - Electric heater - Google Patents

Description

  The present invention relates to an electric heater provided with a heating element that generates heat by the supply of power.

  For example, an electric heater for heating air for air conditioning may be disposed in a vehicle air conditioner. As this type of electric heater, there is known one provided with a heating element composed of a PTC element that generates heat when power is supplied (see, for example, Patent Documents 1 and 2). That is, the electric heater according to Patent Documents 1 and 2 includes a plurality of heat generating elements, a heat radiating element including fins disposed between the heat generating elements, and a housing for housing the heat generating element and the heat radiating element. After the external air flows in from the upstream opening formed in and is heated, it flows out from the downstream opening.

  Each heating element holds a pair of sheet metal bands, a PTC element disposed between the sheet metal bands, and a pair of sheet metal bands and a PTC element, as described in FIG. 7 of each document. And a placement frame. The placement frame has a holding projection engaged from the outer surface to one sheet metal band and a holding projection engaged from the outer surface to the other sheet metal band, and one sheet metal band and the other sheet A part of the arrangement frame is interposed between the metal band and the metal band.

  Also, inside the housing, a spring element for pressing the heat generating element and the heat radiating element in the stacking direction is disposed, and a compressive force is applied to the heat generating element and the heat radiating element by the spring element. There is. That is, the housing is divided into two in the flow direction of the external air, and is configured of an upper housing disposed on the upstream side and a lower housing disposed on the downstream side. Then, when the upper housing and the lower housing are combined, the spring element is disposed between the upper housing and the lower housing as described in FIG. Is gradually closed so that the closing force at that time pushes the spring element into the interior of the housing.

Patent No. 4880648 Patent No. 4939490

  However, in the above Patent Documents 1 and 2, when assembling the spring element, the spring element is pushed into the housing simultaneously with the operation of closing the upper housing and the lower housing. At this time, the reaction force of the spring element may act to partially deform the upper housing and the lower housing, and the reaction force of the spring element inhibits the operation of closing the upper housing and the lower housing. It is possible that the assembly becomes difficult as a result.

  The present invention has been made in view of such a point, and an object of the present invention is to improve assembling workability when a spring member for applying a compressive force is provided inside a housing. .

  In order to achieve the above object, in the present invention, the spring member can be assembled from the outside to the inside of the housing.

The first invention is
A heat generating portion having a heat generating element that generates heat by supply of power;
Fins for transferring the heat of the heat generating portion to the external air;
A housing for holding the heat generating portion and the fin in a state in which the heat generating portion and the fin are stacked and arranged in a direction intersecting the flow direction of the external air;
In the electric heater, the electric heater includes a spring member which is assembled to the housing and which exerts a compressive force on the heat generating portion and the fins in the stacking direction.
The housing is formed by combining an upstream housing component and a downstream housing component divided in the flow direction of the external air,
The housing is formed with an opening through which external air flows, and the spring member is inserted from the outside of the housing into the inside of the opening .
The housing is provided with a reinforcement extending transversely to the opening,
The said spring member is characterized by the notch part which the said reinforcement part fits in is formed .

According to this configuration, when the heat generating portion and the fin are assembled to the housing, the heat generating portion and the fin are disposed between the upstream housing component and the downstream housing component, and the spring member is placed outside. And combining the upstream housing component and the downstream housing component. At this time, since the reaction force by the spring member does not act on the upstream side housing component or the downstream side housing component, the assembling workability is good. Thereafter, the spring member is inserted into the interior of the housing through the opening of the housing. At this time, the reaction force of the spring member acts, but since the heat generating portion and the fin are already held inside the housing, it is sufficient to press only the spring member, and the assembling workability is good.

In addition , since the opening through which the external air flows is the insertion portion, it is possible to insert the spring member into the inside of the housing by using the opening.

Moreover , the strength of the housing is enhanced by providing the reinforcing portion. And when inserting a spring member in the inside of a housing, it becomes possible to avoid interference with a reinforcement part and to assemble a spring member by fitting a reinforcement part to a notch of a spring member. Also, the positioning of the spring member can be performed by the reinforcing portion.

A second invention relates to the first invention,
The notch is formed to extend in the insertion direction of the spring member into the opening .

  According to this configuration, when inserting the spring member into the interior of the housing, it becomes possible to assemble the spring member in a state in which the reinforcing portion of the housing is inserted into the cutout portion of the spring member.

In a third aspect of the present invention, in the first or second aspect ,
A predetermined gap is provided between the reinforcing portion and the heat generating portion.

  According to this configuration, since the reinforcing portion of the housing and the heat generating portion do not contact strongly, the compression force by the spring member reliably acts on the heat generating portion and the fin.

A fourth invention is according to any one of the first to third inventions,
The spring member is characterized in that a contact portion that contacts the reinforcing portion from the outside of the housing is provided.

  According to this configuration, when the spring member is inserted into the interior of the housing, the abutment portion of the spring member abuts against the reinforcement portion of the housing from the outside, which makes it possible to stop the insertion of the spring member. .

According to the first invention, since the spring member can be assembled from the outside of the housing to the inside, the heat generating portion and the fin can be assembled to the housing with the spring member placed outside, and thereafter, The spring member can be inserted into the housing through the opening and assembled. As a result, assembling workability can be improved.

Also , the opening of the housing can be used to insert the spring member into the interior of the housing.

Further , the housing is provided with the reinforcing portion extending so as to cross the opening, and the notch portion in which the reinforcing portion is fitted is formed in the spring member, so that interference with the reinforcing portion is avoided when enhancing the strength of the housing by the reinforcing portion. Thus, the spring member can be easily assembled. Also, the positioning of the spring member can be performed by the reinforcing portion.

According to the second aspect of the invention, since the notch portion of the spring member is formed to extend in the insertion direction, the assembling workability of the spring member can be further improved.

According to the third invention, since the predetermined gap is provided between the reinforcing portion of the housing and the heat generating portion, it is possible to suppress strong contact between the reinforcing portion of the housing and the heat generating portion. Thereby, the compression force by the spring member can be reliably applied to the heat generating portion and the fin.

According to the fourth aspect of the invention, the contact portion that contacts the reinforcing portion is provided on the spring member, so that the insertion of the spring member can be stopped in a state where the spring member is inserted to a predetermined position.

It is the perspective view which looked at the electric heater which concerns on embodiment from the flow direction downstream side of external air. It is the FIG. 1 equivalent view in the state which removed the left side cap and the right side cap. It is the III-III sectional view taken on the line in FIG. It is a perspective view of a 1st heat-emitting part. It is an exploded perspective view of the 1st exothermic part. It is the figure which expanded the part enclosed with the dashed-dotted line in FIG. 4, and was seen from diagonally upward. It is a top view which shows a part of spring member. It is a perspective view which shows the attachment point of a spring member. It is a perspective view which shows the state in the middle of inserting in the housing of a spring member. FIG. 7 is a cross-sectional view taken along line XX in FIG. It is the FIG. 10 equivalent view which concerns on a modification.

  Hereinafter, embodiments of the present invention will be described in detail based on the drawings. The following description of the preferred embodiments is merely illustrative in nature, and is not intended to limit the present invention, its applications, or its applications.

  FIG. 1 is a perspective view of an electric heater 1 according to an embodiment of the present invention. The electric heater 1 is, for example, disposed in a vehicle air conditioner installed in an automobile (not shown) and used as an air heater for heating air for air conditioning, and is a so-called PTC heater. The electric heater 1 can be used as an auxiliary air heater, or can be used as a main air heater by increasing the amount of heating. Electric power is supplied to the electric heater 1 from a battery (not shown) mounted on the vehicle. Although not shown, the electric heater 1 can be used to heat various air other than the air heater of the air conditioner.

  Although FIG. 1 and FIG. 2 describe the case where the electric heater 1 is viewed from the downstream side on the basis of the flow direction of the external air, the electric heater 1 is defined as the downstream side in FIG. 1 and FIG. May be used as the upstream side. Further, in the left-right direction of the electric heater 1, the side which is the right when viewed from the downstream side of the flow direction of the external air is referred to as "right" and the side which is the left is referred to as "left".

  The electric heater 1 includes a housing 3 for holding the first to fourth heat generating parts A1 to A4, the fins 2, the first to fourth heat generating parts A1 to A4 and the fins 2, and a spring member 4. , And a left side cap 5 and a right side cap 6 and has a generally rectangular shape elongated in the left-right direction as a whole. The first to fourth heat generating parts A1 to A4 are all the same, and as shown in FIG. Further, as shown in FIG. 2, the first heat generating portion A1 is positioned at the top, the fourth heat generating portion A4 is positioned at the bottom, and the second heat generating portion A2 is located below the first heat generating portion A1. The third heat generating portion A3 is located between the second heat generating portion A2 and the fourth heat generating portion A4. The fins 2 are disposed on the upper and lower surfaces of the first heat generating portion A1, and also on the upper and lower surfaces of the second heat generating portion A2, the upper and lower surfaces of the third heat generating portion A3, and the upper and lower surfaces of the fourth heat generating portion A4. It is arranged. That is, the first to fourth heat generating portions A1 to A4 and the fins 2 are stacked and arranged in the vertical direction which is a direction intersecting the flow direction of the external air.

  The fins 2 are corrugated fins made of, for example, a thin plate material made of aluminum alloy, and are heat transfer members for transferring the heat of the first to fourth heat generating portions A1 to A4 to the external air. The continuous direction of the waveform in the fin 2 is the left-right direction of the electric heater 1. The fins 2 are continuous from the left end to the right end of the housing 3 inside the housing 3. External air flows through the fins 2. Further, power may be controlled to be supplied individually to the first to fourth heat generating parts A1 to A4, or power may be supplied to all of them.

  As shown in FIG. 5, the first heat generating portion A1 includes a plurality of PTC elements 10, 10,..., An upper electrode plate (first conductive member) 12 and a lower electrode plate (second conductive member) 13 And the holder 14. Each PTC element 10 is a heat generating element that generates heat when power is supplied, and is formed in a plate shape long in the left-right direction of the electric heater 1. In this embodiment, the number of PTC elements 10 is four, and they are spaced apart from each other in the left-right direction. However, the number and arrangement of the PTC elements 10 are not limited to this.

  The upper electrode plate 12 and the lower electrode plate 13 are formed by molding a conductive plate material made of metal, and are electrically connected in contact with the respective PTC elements 10. The upper electrode plate 12 extends in the left-right direction. A through hole 12 a penetrating in the vertical direction (the thickness direction of the upper electrode plate 12) is formed at the right end of the upper electrode plate 12. The left end portion of the upper electrode plate 12 is a connecting portion 12 b formed so as to extend leftward after being bent upward. A harness (not shown) to which electric power of a battery mounted on a vehicle can be connected can be connected to the connection portion 12b.

  The lower electrode plate 13 also extends in the left-right direction. At the right end portion of the lower electrode plate 13, a through hole 13a penetrating in the vertical direction (the thickness direction of the lower electrode plate 13) is formed. The left end portion of the lower electrode plate 13 is a connecting portion 13 b formed to extend to the left. As shown in FIG. 4, the connection portion 13 b of the lower electrode plate 13 and the connection portion 12 b of the upper electrode plate 12 are vertically separated from each other. The connection portion 13b of the lower electrode plate 13 can also connect a harness (not shown).

  As shown in FIGS. 3 and 10, the PTC elements 10, 10,... Are disposed between the upper electrode plate 12 and the lower electrode plate 13. That is, the upper electrode plate 12 and the lower electrode plate 13 sandwich the PTC elements 10, 10, ... from both sides in the stacking direction of the first to fourth heat generating portions A1 to A4 and the fins 2, and the PTC element 10, 10 are arranged to be in contact with the PTC elements 10 to supply power from the outside to the PTC elements 10.

  The holder 14 is made of a resin material having heat resistance and electrical insulation, and is for holding and integrating the PTC elements 10,..., The upper electrode plate 12 and the lower electrode plate 13. As shown in FIG. 5, the holder 14 has a frame shape surrounding the peripheral portions of the PTC elements 10, 10,..., The upper electrode plate 12 and the lower electrode plate 13. That is, the holder 14 is provided with the downstream side wall 20 extending along the edge of the upper electrode plate 12 and the lower electrode plate 13 on the downstream side in the external air flow direction, and the outer air flow of the upper electrode plate 12 and the lower electrode plate 13 The upstream side wall 21 extending along the upstream side edge, the left wall 22 extending to connect the left ends of the downstream side wall 20 and the upstream side wall 21 with each other, the downstream side wall 20 and the upstream side wall 21 And a right wall portion 23 extending to connect the right ends of the two. An upper portion of the left wall portion 22 protrudes upward more than upper portions of the downstream side wall portion 20 and the upstream side wall portion 21. The connection portion 12b of the upper electrode plate 12 is fitted to the upper portion of the left wall portion 22 from above. Further, the connection portion 13b of the lower electrode plate 13 is fitted to the lower portion of the left wall portion 22 from below.

  The upper portion of the right wall portion 23 of the holder 14 protrudes upward more than the upper portions of the downstream side wall portion 20 and the upstream side wall portion 21, and the lower portion of the right wall portion 23 of the holder 14 is a lower portion of the downstream side wall portion 20 and the upstream side wall portion 21 It protrudes more downward than it is. Therefore, when the dimensions of the downstream side wall 20, the upstream side wall 21, the left wall 22 and the right side wall 23 are compared in the vertical direction, the downstream side wall 20 and the upstream side wall 21 are the shortest. As shown in FIGS. 3 and 10, the dimensions of the downstream side wall 20 and the upstream side wall 21 in the vertical direction are the size in the vertical direction of the PTC element 10, the size in the vertical direction of the upper electrode plate 12, and the lower electrode plate 13. It is set to be longer than the length obtained by adding the vertical dimension of.

  As shown in FIG. 5, in the downstream side wall portion 20, four flat portions 20a, 20a,... Are provided at intervals in the left-right direction. Each flat portion 20a extends in the vertical direction. As shown in FIGS. 3 and 10, the inner surface (the inner surface of the holder 14) of each flat portion 20a of the downstream side wall portion 20 is engaged with the upper electrode plate 12 from the side (upper side) opposite to the PTC element 10 side. Downstream upper engagement portion (first engagement portion) 20b, and a downstream lower engagement portion engaged with the lower electrode plate 13 from the opposite side (lower side) of the PTC 2 engaging portion) 20c, and a downstream side projecting portion 20d which protrudes inward of the holder 14 from between the downstream side upper engaging portion 20b and the downstream side lower engaging portion 20c. The downstream upper engaging portion 20 b and the downstream lower engaging portion 20 c are each formed of a projection that protrudes inward of the holder 14.

  The downstream upper engaging portion 20b is formed at the right side of the flat portion 20a, while the downstream lower engaging portion 20c is formed at the left side of the flat portion 20a. When the holder 14 is viewed from the stacking direction of the first to fourth heat generating portions A1 to A4 and the fins 2, the downstream upper engaging portion 20b and the downstream lower engaging portion 20c are arranged so as not to overlap with each other. ing. As a result, when the holder 14 is formed, the downstream upper engagement portion 20 b and the downstream lower engagement portion 20 c do not become an undercut portion. Therefore, since it is not necessary to provide the mold with a slide mold or the like for avoiding the undercut portion, the cost of the mold can be reduced.

  The vertical separation dimension of the downstream upper engagement portion 20b and the downstream lower engagement portion 20c is the vertical dimension of the PTC element 10, the vertical dimension of the upper electrode plate 12, and the vertical direction of the lower electrode plate 13. It is set longer than the length which added the dimension of. Further, the dimension in the stacking direction (vertical direction) of the downstream side protrusion 20 d is set shorter than the dimension in the stacking direction of the PTC element 10.

  Further, as shown in FIG. 5, four flat portions 21a, 21a,... Are also provided on the upstream side wall portion 21 at intervals in the left-right direction. Each flat portion 21 a is disposed to face each flat portion 20 a of the downstream side wall portion 20 and extends in the vertical direction. As shown in FIGS. 3 and 10, the inner surface (the inner surface of the holder 14) of each flat portion 21a of the upstream side wall portion 21 is engaged with the upper electrode plate 12 from the side (upper side) opposite to the PTC element 10 side. An upstream upper engagement portion (first engagement portion) 21b, and an upstream lower engagement portion (a first engagement portion) engaged with the lower electrode plate 13 from the side (lower side) opposite to the PTC (2 engaging portion) 21c, and an upstream projecting portion 21d projecting inward of the holder 14 from between the upstream upper engaging portion 21b and the upstream lower engaging portion 21c. The upstream upper engaging portion 21 b and the upstream lower engaging portion 21 c are each formed of a projection that protrudes inward of the holder 14.

  The upstream upper engaging portion 21b is formed on the left side of the flat portion 21a, while the upstream lower engaging portion 21c is formed on the right side of the flat portion 20a. When the holder 14 is viewed from the stacking direction of the first to fourth heat generating portions A1 to A4 and the fins 2, the upstream upper engaging portion 21b and the upstream lower engaging portion 21c are arranged so as not to overlap with each other. ing. As a result, since the upstream upper engaging portion 21 b and the upstream lower engaging portion 21 c do not become an undercut portion when molding the holder 14, the mold cost can be reduced.

  The separation dimensions of the upstream upper engagement portion 21b and the upstream lower engagement portion 21c in the vertical direction are the vertical dimension of the PTC element 10, the vertical dimension of the upper electrode plate 12, and the vertical direction of the lower electrode plate 13. It is set longer than the length which added the dimension of. Further, the dimension in the stacking direction (vertical direction) in the upstream side protrusion 21 d is set shorter than the dimension in the stacking direction in the PTC element 10.

  The separation dimension between the downstream upper engagement portion 20b and the downstream lower engagement portion 20c is set as described above, and the separation dimension between the upstream upper engagement portion 21b and the upstream lower engagement portion 21c is as described above. By setting the upper side electrode plate 12 and the lower side electrode plate 13 together with the PTC element 10, it becomes possible to move the upper side electrode plate 12 and the lower side electrode plate 13 in the vertical direction inside the holder 14. That is, the upper electrode plate 12 is vertically arranged between the downstream upper engagement portion 20b and the downstream lower engagement portion 20c and between the upstream upper engagement portion 21b and the upstream lower engagement portion 21c. It can be moved, which allows for displacement in the direction of coming in and out of the lower electrode plate 13. Similarly, the lower electrode plate 13 is disposed between the downstream upper engagement portion 20b and the downstream lower engagement portion 20c, and between the upstream upper engagement portion 21b and the upstream lower engagement portion 21c. It can also be moved in the vertical direction, which allows for displacement in the direction in which the upper electrode plate 12 is moved in and out.

  The second to fourth heat generating portions A2 to A4 have the same structure as the first heat generating portion A1, and thus the description thereof is omitted.

  Next, the structure of the housing 3 will be described. As shown in FIGS. 1 to 3, the housing 3 is formed by combining an upstream housing component 30 and a downstream housing component 31 which are divided in the flow direction of the external air. The upstream housing component 30 and the downstream housing component 31 are made of a resin material having heat resistance and electrical insulation. As shown in FIG. 3, the upstream housing component 30 is formed with an upstream opening 30 a through which external air flows. Further, the downstream side housing component 31 also has a downstream side opening 31a through which the external air flows. The upstream opening 30a and the downstream opening 31a have substantially the same shape and the same size. The downstream side opening 31a of the downstream side housing component 31 is an insertion part for inserting the spring member 4 from the outside of the housing 3 into the inside, although the details will be described later.

  As shown in FIG. 3, the downstream housing component 31 is formed with a fitting protrusion 31 b that protrudes toward the upstream side. On the other hand, in the upstream housing component 30, a fitting recess 30 b in which the fitting convex part 31 b of the downstream housing component 31 is fitted is formed. In a state in which the upstream side housing component 30 and the downstream side housing component 31 are combined, the fitting convex portion 31 b is fitted in a state of being inserted into the fitting concave portion 30 b.

  As shown in FIGS. 1 and 2, the downstream housing component 31 is provided with a plurality of reinforcing portions 31c extending in the vertical direction so as to cross the downstream opening 31a in the horizontal direction. In this embodiment, the reinforcing portion 31 c is in the form of a rod extending obliquely, but not limited to this, for example, it may extend in the vertical direction.

  The upper end portion of the reinforcing portion 31 c is continuous with the lower surface of the upper wall portion of the downstream side housing component 31. The lower end portion of the reinforcing portion 31 c is continuous with the upper surface of the lower wall portion of the downstream side housing component 31. Further, upper ends or lower ends of two adjacent reinforcing portions 31c are integrated.

  As shown in FIG. 3, the upstream housing component 30 is also provided with a reinforcing portion 30 c similar to the downstream housing component 31.

  As shown in FIG. 3, between the reinforcing portion 31 c of the downstream side housing component 31 and the holder 14 of the first heat generating portion A 1, and the reinforcing portion 30 c of the upstream side housing component 30 and the first heat generating portion A 1 A predetermined gap is formed between the holder 14 and the holder 14. That is, the outer surface of the upstream side wall 21 of the holder 14 is separated from the inner surface of the reinforcing portion 30 c of the upstream housing component 30, and the outer surface of the downstream side wall 20 of the holder 14 is of the downstream housing component 31. It is separated from the inner surface of the reinforcing portion 31c. As a result, the first to fourth heat generating parts A1 to A4 do not come in strong contact with the reinforcing parts 30c, 31c, and when the compression force by the spring member 4 acts inside the housing 3, the first to fourth The first to fourth heat generating portions A1 to A4 can move in the vertical direction.

  Next, the spring member 4 will be described. The spring member 4 is assembled inside the housing 3 and applies a compressive force to the first to fourth heat generating portions A1 to A4 and the fins 2 in the stacking direction thereof. The spring member 4 is formed, for example, by molding a resilient metal plate and extends from the left end to the right end of the housing 3. As shown in FIGS. 7 to 9, the spring member 4 is bent upward from the plate portion 40 extending in the left-right direction and the edge portion of the plate portion 40 on the upstream side in the flow direction of external air, and then extends downstream. A plurality of upstream biasing portions 41, and a plurality of downstream biasing portions 42 extending upward after bending upward from the downstream end of the flow direction of the external air in the plate portion 40 are provided. . The upstream biasing portions 41 are spaced apart from each other in the left-right direction, and the downstream biasing portions 42 are also provided.

  The lower surface of the plate portion 40 of the spring member 4 is in contact with the upper surface of the fin 2 disposed at the upper end portion. The upper end portions of the upstream biasing portion 41 and the downstream biasing portion 42 are in contact with the inner surface of the upper wall portion of the housing 3. The upstream side biasing portion 41 and the downstream side biasing portion 42 are mainly elastically deformed between the fin 2 at the upper end portion and the inner surface of the upper wall portion of the housing 3 to form the first to fourth heat generating portions A1 to A1. A compressive force is applied to the A 4 and the fins 2 in the stacking direction.

  As shown in FIG. 7, the downstream housing component 31 is provided between the adjacent upstream biasing portions 41 and 41 and between the adjacent downstream biasing portions 42 and 42 in the plate portion 40 of the spring member 4. The notch part 40a which the reinforcement part 31c of 3 fits is formed. The notch 40 a is formed so as to extend in the downstream direction from the upstream edge of the plate 40, that is, in the insertion direction when the spring member 4 is inserted into the downstream opening 31 a. It is open at the upstream edge. Inclined edge portions 40b for guiding the reinforcing portion 31c into the notch portion 40a are provided on the upstream side of the left and right edges of the notch portion 40a.

  The plate portion 40 of the spring member 4 is provided with an abutting portion 43 that abuts the reinforcing portion 31 c of the downstream side housing component 31 from the outside of the housing 3. The abutting portion 43 is formed in a plate shape extending upward from the vicinity of the edge portion on the downstream side in the flow direction of the external air in the cutout portion 40a. The reinforcing portion 31 c is in contact with the surface of the contact portion 43 on the downstream side in the flow direction of the external air.

  Next, the structures of the left cap 5 and the right cap 6 will be described. The left cap 5 and the right cap 6 are made of a resin material having heat resistance and electrical insulation. As shown in FIG. 1, the left side cap 5 covers the connecting portion 12b and the connecting portion 13b of the first to fourth heat generating portions A1 to A4, and the left end portion of the upstream side housing component 30 and the downstream side housing component 31 It is formed to cover the The right side cap 6 is formed to cover the right end portions of the upstream housing component 30 and the downstream housing component 31. The left cap 5 and the right cap 6 are attached after the upstream housing component 30 and the downstream housing component 31 are combined.

  Next, an assembly procedure of the electric heater 1 configured as described above will be described. First, the first to fourth heat generating portions A1 to A4 and the fins 2 are stacked and placed on one of the upstream housing component 30 and the downstream housing component 31. At this time, as shown in FIG. 10, the downstream upper engaging portion 20b and the upstream upper engaging portion 21b of the holder 14 of the first heat generating portion A1 engage with the upper electrode plate 12 from the upper side, and Since the lower engaging portion 20 c and the upstream lower engaging portion 21 c are engaged from the lower side of the lower electrode plate 13, the upper electrode plate 12 and the lower electrode plate 13 do not come off the holder 14. , And can be kept integrated with the PTC element 10. Therefore, when assembling the first to fourth heat generating parts A1 to A4 together with the fins 2 into the housing 3, the assembling workability is improved. At this time, the spring member 4 is not assembled but removed.

  Then, the upstream housing component 30 and the downstream housing component 31 are combined. At this time, the fitting convex portion 31 b is inserted into and fitted to the fitting recess 30 b to integrate the upstream housing component 30 and the downstream housing component 31. When the upstream housing component 30 and the downstream housing component 31 are combined, since the spring member 4 is removed, the reaction force from the spring member 4 acts on the upstream housing component 30 and the downstream housing component 31. Since it is not done, assembling workability is good.

  Thereafter, as shown in FIGS. 8 and 9, the spring member 40 is inserted into the housing 3 through the downstream opening 31 a of the housing 3. When inserted into the housing 3, the reaction force of the spring member 40 acts, but since the first to fourth heat generating parts A1 to A4 and the fins 2 are already held inside the housing 3, the spring member It is sufficient to press only 4 and the assembling workability is good.

  After the spring member 4 is assembled, the compression force by the spring member 4 also acts on the first to fourth heat generating portions A1 to A4. At this time, as shown in FIG. 3, since the upper electrode plate 12 held by the holder 14 is displaceable in the direction of coming in and out of contact with the lower electrode plate 13, the upper electrode plate 12, the lower electrode Even if the thickness and shape of the plate 13 and the PTC element 10 vary, the pressure contact force between the upper electrode plate 12 and the PTC element 10 and the pressure force between the lower electrode plate 13 and the PTC element 10 are sufficiently ensured. It becomes possible. Thereby, the calorific value decrease of the PTC element 10 can be suppressed.

  Further, when the spring member 4 is inserted into the housing 3, the spring member 4 can be assembled in a state in which the downstream reinforcing portion 31 c of the housing 3 is inserted into the notch 40 a of the spring member 4. Because of this, assembling workability becomes good.

  Further, since a predetermined gap is provided between the reinforcing portions 30c and 31c of the housing 3 and the heat generating portions A1 to A4, strong contact between the reinforcing portions 30c and 31c and the heat generating portions A1 to A4 can be suppressed. . Thereby, the compression force by the spring member 4 can be reliably applied to the heat generating portions A1 to A4 and the fins 2.

  Moreover, since the contact part 43 which contacts the downstream side reinforcement part 31c was provided in the spring member 4, the insertion of the said spring member 4 can be stopped in the state which inserted the spring member 4 to the predetermined position.

  The lower electrode plate 13 may be insert-molded on the holder 14 as in the modification of the embodiment shown in FIG. In this case, although the lower electrode plate 13 is not displaced with respect to the holder 14, the upper electrode plate 12 can be allowed to displace in the direction in which the lower electrode plate 13 is moved toward and away from the lower electrode plate 13.

  The embodiments described above are merely illustrative in every respect and should not be construed as limiting. Furthermore, all variations and modifications that fall within the equivalent scope of the claims fall within the scope of the present invention.

  As described above, the electric heater according to the present invention can be used, for example, as an air heater of a vehicle air conditioner.

Reference Signs List 1 electric heater 2 fin 3 housing 4 spring member 30 upstream housing component 31 downstream housing component 31 a opening (insertion portion)
31c Reinforcement part 40a Notch part 43 Abutment parts A1 to A4 First to fourth heat generation parts

Claims (4)

A heat generating portion having a heat generating element that generates heat by supply of power;
Fins for transferring the heat of the heat generating portion to the external air;
A housing for holding the heat generating portion and the fin in a state in which the heat generating portion and the fin are stacked and arranged in a direction intersecting the flow direction of the external air;
In the electric heater, the electric heater includes a spring member which is assembled to the housing and which exerts a compressive force on the heat generating portion and the fins in the stacking direction.
The housing is formed by combining an upstream housing component and a downstream housing component divided in the flow direction of the external air,
The housing is formed with an opening through which external air flows, and the spring member is inserted from the outside of the housing into the inside of the opening .
The housing is provided with a reinforcement extending transversely to the opening,
An electric heater characterized in that the spring member is formed with a notch into which the reinforcing portion is fitted . In the electric heater according to claim 1 ,
The electric heater according to claim 1, wherein the notch extends in a direction in which the spring member is inserted into the opening . In the electric heater according to claim 1 or 2 ,
A predetermined gap is provided between the reinforcing portion and the heat generating portion. In the electric heater according to any one of claims 1 to 3 ,
The said spring member is provided with the contact part contact | abutted from the outer side of the said housing with respect to the said reinforcement part. The electric heater characterized by the above-mentioned.

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