JP2005108808A - Electric heater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric heater with the number of parts decreased and stably supporting a heating element by side frames. <P>SOLUTION: The electric heater 2 has a heat radiating fin 32; a heating element 330 generating heat by energization; a holding tool 33 holding the element 330; a heating element 3 structured by layering electrode plates 31 to impress power on the element 330. A heated medium passes through near the fin 32 toward the other surface 306 from one surface 305 stretched by both end faces 301, 302 in the layered direction of the heating element 3 and both side faces 303, 304 crossing both the end faces 301, 302. The heater 2 has first and second holding frames 21, 22 on both the end faces 301, 302 in the layered direction of the heating element 3, and has side frames 19, 1 on both the side faces 303, 304 of the heating element 3. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an electric heater that employs a positive temperature coefficient thermistor or the like as a heating element.

As shown in FIG. 20, a pair of first and second mounting frames 91 and 92 arranged substantially in parallel, and perpendicular to the first and second mounting frames 91 and 92 and the first and second mounting frames 91. , 92 are respectively held by side mounting frames 93, 94, and an electric heater 9 in which a heating element 95 is arranged in a plane formed by the first, second and side mounting frames 91-94. Are known.
The heating element 95 is formed by stacking heat radiation fins 951, heating elements 952, and electrode plates 953 for applying electric power to the heating elements 952 substantially parallel to each other. The first and second mounting frames 91 and 92 are substantially perpendicular to the stacking direction of the heating elements 95, and the side mounting frames 93 and 94 are approximately parallel to the stacking direction.
In the electric heater 9, the heating element 95 is laminated between the first mounting frame 91 and the upper end face of the heating element 95 and between the second mounting frame 92 and the lower end face of the heating element 95. Spring members 910 and 920 that exhibit an elastic force (restoring force) from the outside to the inside are arranged.

When the electric heater 9 is assembled, the side mounting frames 93 and 94 are moved to the first and second mounting frames 93 and 94 in a state where the heating elements 95 are pressed from the first and second mounting frames 91 and 92 so that the spring materials 910 and 920 are bent. 2 It fixes to the edge part of the attachment frames 91 and 92.
Due to this fixing, the heat generating body 95 receives a compressive force in the stacking direction, and the heat dissipating fins 951, the heat generating elements 952, and the electrode plate 953 that are constituent elements of the heat generating body 95 are brought into close contact with each other by the compressive force. It is fixed in 94.

In the electric heater 9, electric power is applied from the electrode plate 953 to the heat generating element 952, and the heat generating element 952 generates heat. The heat generated in the heat generating element 952 is thermally conducted to the heat radiating fins 951 through the electrode plate 953, and heat conduction is generated from the heat radiating fins 951 to the heated medium passing through the vicinity of the heat radiating fins 951. Function.
Therefore, it is desirable that the heat dissipating fins 951, the heat generating elements 952, and the electrode plates 953 that are constituent elements of the heat generating element 95 are sufficiently in close contact with each other.
In the electric heater 9 according to FIG. 20, the spring members 910 and 920 apply a compressive force in the stacking direction to the heating element 95, thereby realizing mutual contact between the components of the heating element 95.
The following Patent Documents 1 and 2 have the same configuration as that of FIG. 20 and the effect of the spring material.

Japanese Patent Publication No. 8-3391 Japanese Patent No. 3274234

By the way, in the electric heater 9 according to the above-described prior art, the heating element 95 is integrally held by using the spring members 910 and 920, the first and second mounting frames 91 and 92, and the side surface mounting frames 93 and 94. Yes. Thus, in order to integrally hold the heating element 95, it is necessary to use the spring materials 910 and 920 in addition to the first and second mounting frames 91 and 92 and the side surface mounting frames 93 and 94.
Therefore, there has been a demand for a new device that can reduce the number of parts that contribute to the above-described laminated integrated holding.

  The present invention has been made in view of such conventional problems, and is intended to provide an electric heater that can reduce the number of parts and can stably support a heating element by a side frame. Is.

The present invention has a heat-radiating fin, a heat-generating element that generates heat when energized, a holder that holds the heat-generating element, and a heating element configured by laminating electrode plates that supply power to the heat-generating element. An electric heater that passes in the vicinity of the radiation fins,
The electric heater has first and second holding frames on both end surfaces of the heating element in the stacking direction, and side frames on both side faces of the heating element,
The side frame includes a support portion disposed on a side surface of the heating element, and a pair of fixing pieces that are formed at both ends of the support portion and press the heating element in the stacking direction.
The heating element and the side frame are engaged with each other to form a displacement restricting portion that restricts the displacement of the heating element in the front direction. Item 1).

The electric heater of the present invention can not only support the heating element from the side by the side frame, but also support the heating element in the stacking direction.
That is, the side frame has the support part and a pair of fixing parts, and the support part is opposed to the side surface of the heating element formed by stacking the radiation fins, the holder, and the electrode plate. The body can be supported from the side. Moreover, a pair of fixing | fixed part can press and support the said heat generating body from the both sides in the lamination direction of the said heat generating body.

Therefore, the side frame not only supports the heating element from the side, but also supports the heating element by pressing it in the stacking direction. Accordingly, the side frame can have both the role of the frame member and the role of the spring member, and it is not necessary to separately provide the spring member in order to hold the heating element in the stacking direction.
Further, the heat generating element and the side frame form a displacement restricting portion, and the side frame can also restrict the heat generating element from being displaced in the front direction. Therefore, the side frame can also support the heating element in the front direction.
In addition, a front direction means the direction orthogonal to a side (horizontal direction) and a lamination direction.

  Therefore, according to the electric heater, the number of parts can be reduced, and the heating element can be stably supported by the side frame.

  The electric heater of the present invention can use a PTC (Positive Temperature Coefficient) element as a heating element. A PTC element has a property that electrical resistance rapidly increases above a specific temperature. Therefore, it generates heat when energized. However, when the temperature at which heat is generated exceeds a predetermined temperature, the electrical resistance becomes too high and almost no current is generated. It will not flow and will not generate heat above a certain temperature. Therefore, by using this element, the heater can be effectively heated and overheating of the heater can be prevented.

Moreover, it is preferable that the side frame has a slit which is a through hole along the side surface of the heating element, and the deviation regulating portion is formed by inserting the heating element into the slit. (Claim 2).
In this case, since the slit is formed in the side frame, the displacement restricting portion can be configured easily.

Moreover, it is preferable that the said holder in the said heat generating body consists of a main-body part which hold | maintains the said heat generating element, and a terminal protrusion part narrower than this main-body part and inserted in the said slit (Claim 3).
In this case, the step portion formed between the main body portion and the terminal projecting portion in the holder is opposed to the inner surface of the side frame, and the terminal projecting portion is opposed to the inner peripheral surface of the slit. . Therefore, the side frame can effectively regulate the positional deviation of the heating element in the side and front directions.

The electrode plate has a terminal portion protruding from one side surface of the heating element, and the terminal portion can be inserted into a slit in at least one of the pair of side frames.
In this case, the terminal portion of the electrode plate can be protruded to the side of the side frame, that is, to the side of the electric heater while being inserted through the slit. Therefore, the terminal part in an electrode plate can be arrange | positioned using the inside of a slit, and an electric heater can be comprised compactly.

Further, the holder in the heating element has a holding recess for holding the side frame in the front direction, and the side frame is inserted into the holding recess from a side surface of the holder. In addition, the displacement restricting portion can be formed (claim 4).
In this case, since the holding recess is formed in the holder, the deviation restricting portion can be easily configured. Moreover, while the bottom face in the holding | maintenance recessed part of a holder faces a side part frame from the side, a pair of inner wall face in a holding | maintenance recessed part respectively opposes a side part frame from a front direction. Therefore, the side frame can effectively regulate the positional deviation of the heating element in the side and front directions.

The side frame is preferably made of an elastic metal material.
In this case, the heating element can be held by using the elastic force of the side frame, and the end (the surface in the stacking direction) of the heating element is pressed in the stacking direction to hold the heating element more stably. Strong holding power can be demonstrated.
Moreover, the heat resistance of a side part frame can be improved by using metal.

(Example 1)
As shown in FIGS. 1 to 11, the electric heater 2 of this example includes a radiation fin 32, a heating element 330 that generates heat when energized, an electrode plate 31 that applies (supplies) power to the heating element 330, first and first It has the heat generating body 3 formed by laminating two insulators 41 and 42. In addition, the electric heater 2 extends from one surface 305 stretched by both end surfaces 301 and 302 in the stacking direction of the heating element 3 and both side surfaces 303 and 304 intersecting the both end surfaces 301 and 302 to the other surface 306. Thus, the medium to be heated is configured to pass in the vicinity of the heat radiating fins 32.

As shown in FIGS. 1 to 11, the electric heater 2 of this example has first and second holding frames 21 and 22 on both end surfaces 301 and 302 in the stacking direction of the heating element 3, respectively. Both side surfaces 303 and 304 have side frames 1 and 19, respectively.
Each side frame 1, 19 is formed with a support portion 10 disposed on each side surface 303, 304 of the heating element 3, and a pair for respectively pressing the heating element 3 in the stacking direction. Fixed pieces 11 and 12. The heating element 3 and the side frames 1 and 19 are engaged with each other to form a displacement restricting portion 6 that regulates the displacement of the heating element 3 in the front direction.

The electrode plate 31 has a terminal portion 311 protruding from the side surface 304 of the heating element 3. Each of the side frames 1 and 19 has a slit 100 that is a through hole along the side surfaces 303 and 304 of the heating element 3.
And each side frame 1 and 19 forms the said displacement control part 6 by inserting the said heat generating body 3 in those each slit 100. As shown in FIG. Further, each side frame 1, 19 has a pair of fixing pieces 11, 12 that press the heating element 3 in the stacking direction via the first and second holding frames 21, 22. 3 is held in the stacking direction.
The terminal portion 311 is inserted into the slit 100 of the side frame 1, and the terminal portion 311 protrudes from the side of the side frame 1.

Details will be described below.
As shown in FIG. 1, in the electric heater 2 of this example, the heat of the heating element 330 is conducted to the radiation fins 32, and the medium to be heated (for example, air) passes from the surface 305 of the heating element 3 toward the surface 306. In doing so, heat is received from the radiation fins 32, and the temperature of the medium to be heated rises.

As shown in FIGS. 1, 2, and 3, the heating element 3 of this example is formed by sequentially laminating a plurality of electrode plates 31, radiation fins 32, and holders 33. More specifically, the heating element 3 includes the first insulator 41, the electrode plate 31, the radiation fin 32, the holder 33 that holds the heating element 330, the electrode plate 31, the radiation fin 32. Two insulators 42 are stacked in this order. The heating element 3 includes five electrode plates 31, five radiation fins 32, and four holders 33 that hold four heating elements 330.
Further, the heating element 3 is prevented from being displaced in the front direction by inserting the protruding portions 333 and the terminal protruding portions 334 of the plurality of holders 33 into the slits 100 of the side frames 1 and 19, respectively. .

Further, the side frames 19, 1 are arranged on the left and right side surfaces 303, 304 of the heating element 3, and the cases 23, 24 are arranged from the outside of the side frames 19, 1.
3 omits the description of the protruding portion 333, the terminal protruding portion 334 (see FIGS. 6, 10, and 11) and the terminal portion 311 that protrude from both side surfaces 303 and 304, and each of the heating elements 3 is omitted. It is the schematic which showed only the lamination | stacking state of components.

  As shown in FIGS. 1 and 2, the radiating fin 32 is composed of two L-shaped frames 321 and 322 and a thin corrugated plate 320, and has a rectangular shape surrounded by the two L-shaped frames 321 and 322. The corrugated plate 320 is accommodated in a space. The L-shaped frames 321 and 322 and the corrugated plate 320 are integrated by welding or brazing. Here, the L-shaped frames 321 and 322 and the corrugated plate 320 are each made of an aluminum-based or copper-based material.

The heating element 330 is made of a barium titanate PTC element.
As shown in FIGS. 1 and 6 to 8, the holder 33 in the heating element 3 is narrower than the main body at the main body holding the heat generating element and at each side end of the main body. The terminal protrusion 334 and the protrusion 333 are formed.
The terminal protruding portion 334 is configured to guide the terminal portion 311 of the electrode plate 31. Further, the protruding portion 333 is formed on the side opposite to the terminal protruding portion 334.
And the terminal protrusion part 334 and the protrusion part 333 are comprised so that it may be inserted in the slit 100 in each side frame 1 and 19, respectively.

In the holder 33, switching surfaces 3341 and 3331 as stepped portions are formed at the boundary between the terminal protruding portion 334 and the protruding portion 333 and the main body portion 331, and the front surfaces of the terminal protruding portion 334 and the protruding portion 333 are also provided. Projecting surfaces 3340 and 3330 are formed on end surfaces in the direction.
Further, the holder 33 has an H-shaped cross section as shown in FIGS. 8, 10, and 11, and has grooves that are open on both sides of the heating element 3 in the stacking direction. This groove holds the radiation fin 32 and the electrode plate 31 and holds and fixes the radiation fin 32 and the electrode plate 31 so as not to jump out from the direction of the surfaces 305 and 306. A plurality of holding holes 332 for holding the heat generating elements 330 are provided on the bottom surface of the main body portion 331.
The electrode plate 31 is a long thin flat metal plate made of a copper-based material, and one end portion is a terminal portion 311 to which a female terminal 261 described later can be connected.

As shown in FIGS. 1 and 2, the first insulator 41 insulates between the electrode plate 31 located at the extreme end in the stacking direction of the heating elements 3 and the first holding frame 21, and the second insulator 42 generates heat. The heat dissipating fins 32 located at the extreme end in the stacking direction of the bodies 3 are insulated from the second holding frame 22.
As shown in FIG. 9, the first insulator 41 is a groove type capable of holding the adjacent electrode plate 31. Like the holder 33, the first insulator 41 is narrower than the main body 411 and the main body 411. The terminal protrusion 44 protrudes from the side of the part 411 and guides the terminal 311 of the electrode plate 31, and the protrusion 43 protrudes from the side opposite to the terminal protrusion 44.

In the first insulator 41, switching surfaces 441 and 431 as stepped portions are formed at the boundary between the terminal protruding portion 44 and the protruding portion 43 and the main body portion 411, and the terminal protruding portion 44 and the protruding portion 43 are formed. Projection surfaces 440 and 430 are formed on the end surface in the front direction. Further, as shown in FIG. 10, the second insulator 42 has the same shape as the first insulator 41, and has a groove shape capable of holding the adjacent heat radiating fins 32 and has protruding portions 45 at both ends. Reference numeral 451 is a switching surface, and reference numeral 450 is a protruding surface.
Further, the first and second insulators 41 and 42 can be configured to have an H-shaped cross section like the holder 33. In some cases, the first and second insulators 41 and 42 can be reduced depending on the number of stacked heat radiating fins 32 and the heating elements 3, the electric polarity of the first and second holding frames 21 and 22, and the like. .

  As shown in FIGS. 1, 10, and 11, the first and second holding frames 21 and 22 are cylindrical hollow members having a square cross section, and have openings 213, 214, 223, and 224 that face the side surface of the heating element 3. . The first and second holding frames 21 and 22 have engaging holes 217, 218, 227, and 228 at both ends in the longitudinal direction for engaging with engaging pieces 235 and 245 of cases 23 and 24, which will be described later.

The cases 23 and 24 are crowned from the outside of the side frames 1 and 19. The left case 23 in FIG. 1 has a rectangular side shape and includes an inner engagement piece 235 extending toward the side frame 19. The inner engagement pieces 235 engage with the left engagement holes 217 and 227 of the first and second holding frames 21 and 22.
The right case 24 in FIG. 1 has flanges 241 at both ends, penetrates the internal engagement piece 245 extending toward the side frame 1 and the case 24, and inserts the terminal portion 311 of the electrode plate 31. In addition, an insertion groove 249 is provided to pull this out. The case 24 has a terminal slit 240 into which the female terminal 261 connected to the terminal portion 311 is inserted on the outer side of the heating element 3.
The case 24 includes a protective case 25 for inserting the female terminal 261 and covering the female terminal 261 from the outside of the case 24 for protection.
The lead wire 262 extending from the female terminal 261 has sockets 263 and 264 that are connected to an external power source (not shown) of the electric heater 2.

As shown in FIGS. 4 and 5, the side frame 1 has an annular shape that bridges between a pair of opposed first and second fixed pieces 11 and 12 and the first and second fixed pieces 11 and 12. It consists of a U-shaped frame consisting of the support part 10.
The first and second fixing pieces 11 and 12 are composed of base end portions 111 and 121 extending from the support portion 10 and distal end portions 113 and 123 extending further from the base end portions 111 and 121, and the base end portions 111 and 121. Between the first and second holding frames 21, 22 and between the first and second holding frames 21, 22. The bent portions 112 and 122 are bent toward the front.

The base end portions 111 and 121 extend from both ends of the support portion 10 in a gentle curve shape, and the tip end portions 113 and 123 are members that extend linearly. The first and second fixing pieces 11 and 12 are bent in a square shape at the boundary between the base end portion 111 and the tip end portion 113, and the base end portion 121 and the tip end portion 123, and these portions become the bent portions 112 and 122, respectively. .
The side frame 1 is made of spring steel such as SK5, and the entire member functions as a spring. That is, the side frame 1 is configured to apply a biasing force in a direction in which the distance between the pair of fixed pieces 11 and 12 is reduced, and between the pair of fixed pieces 11 and 12, The heating element 3 is held in the stacking direction by sandwiching the heating element 3 via the second holding frames 21 and 22.
Further, since the side frame 19 has the same shape as the side frame 1, the description thereof is omitted.

4, 5, and 11, the support portion 10 of the side frame 1 is disposed along the side surface 304 of the heating element 3, and the tip portion of the first fixed piece 11 is the opening 214 of the first holding frame 21. 2 shows a state in which the distal end portion of the second fixed piece 12 is inserted into the opening 224 of the second holding frame 22.
Here, in the bent portion 112, the first fixed piece 11 is brought into contact with the first holding frame 21, and the second fixed piece 12 is brought into contact with the second holding frame 22 in the bent portion 122, so that the side frame 1 is moved into the above-described manner. The first and second holding frames 21 and 22 are fixed.

The assembly of the electric heater 2 of this example will be described.
As shown in FIG. 1, the heat generating element 330 is incorporated in the holder 33, and the first insulator 41, the electrode plate 31, the heat radiating fin 32, the holder 33 holding the heat generating element 330, the electrode plate 31, the heat radiating fin 32. The heat dissipating fins 32 and the second insulator 42 are stacked in this order.
Then, the first holding frame 21 and the second holding frame 22 are disposed at both ends of the first and second insulators 41 and 42. At this time, the groove-shaped holding tool 33 and the groove-shaped first and second insulators 41 and 42 hold the radiation fins 32 and the electrode plate 31, and stabilize the stacked state of the heating elements 3.
The side surface 304 of the heating element 3 in this state is shown in FIG.
In the side surface 304 of the heat generating element 3, the first and second insulators 41 and 42, the electrode plate 31 and the terminal projection 44 of the holder 33, the projection 45, the terminal portion 311, and the terminal projection from the side surface of the radiation fin 32. 334 protrudes, and the terminal portion 311 of the electrode plate 31 is guided by the terminal protruding portions 44 and 334.

Next, as shown in FIGS. 5 (a) and 5 (b), the bending portions 112 and 122 have a larger distance than the distance L1 between the inner wall surfaces 219 and 229 of the first and second holding frames 21 and 22 on the heating element 3 side. The side frame 1 is deformed so that the distance L0 is increased.
As shown in FIG. 5B, the first and second fixing pieces 11 and 12 of the deformed side frame 1 are opened from the side surface 304 side of the heating element 3 to the openings 214 of the first and second holding frames 21 and 22, Plug into 224. In the free state, the side frame 1 is (distance L0 between the bent portions 112 and 122) <(distance L1 between the inner wall surfaces 219 and 229). Therefore, as shown in FIG. While the inner wall surfaces 219 and 229 come into contact with the inner wall surfaces 219 and 229, a compressive force inward in the stacking direction acts on the inner wall surfaces 219 and 229, and the side frame 1 is fixed to the first and second holding frames 21 and 22.

  The side frame 1 can be assembled as follows in addition to being deformed in advance and assembled to the heating element 3 as shown in FIG. That is, the side frame 1 pushes the first and second fixing pieces 11 and 12 from the side surface 304 side of the heating element 3 into the openings 214 and 224 of the first and second holding frames 21 and 22. It can be deformed and assembled to the heating element 3. Further, the side frame 19 can be similarly assembled to the heating element 3.

When the side surface 304 of the heating element 3 in a state where the side frame 1 is assembled is shown in FIG. 11, the switching portions 441, 3341, 451 exposed to the side surface 304 side in FIG. 10, the inner surface 102 (see FIG. 4) of the slit 100 contacts, the inner peripheral surface 101 of the slit 100 contacts the projecting surfaces 440, 3340, 450, and the heating element 3 is inserted into the slit 100 of the side frame 1. Thus, the stacking direction is maintained. At the same time, the terminal portion 311 of the electrode plate 31 guided by the terminal protruding portions 334 and 44 is inserted into the slit 100.
Next, the cases 23 and 24 are crowned from the outside of the side frame 1, and the protective case 25 is crowned outside the case 24.
At this time, the terminal portion 311 of the electrode plate 31 is inserted into the insertion groove 249 of the case 24, and the terminal portion 311 is fixed to the female terminal 261 between the case 24 and the protective case 25.

The electric heater 2 of this example can not only support the heating element 3 from the side by the side frames 1 and 19, but also support the heating element 3 in the stacking direction.
That is, each side frame 1, 19 has a support portion 10 and a pair of fixing pieces 11, 12, and the support portion 10 is opposed to the side surface of the heat generating body 3 so that the heat generating body 3 faces the side. Can be supported from one side. In addition, the pair of fixing pieces 11 and 12 can press and support the heating element 3 from both sides in the stacking direction of the heating elements 3.

Therefore, the side frames 1 and 19 not only support the heating element 3 from the side, but also can support the heating element 3 by pressing it in the stacking direction. Thereby, each side frame 1 and 19 can have the role of a frame member, and the role of a spring member, and it becomes unnecessary to provide a spring member separately in order to hold the heat generating body 3 in the lamination direction.
Further, the heating element 3 and the side frames 1 and 19 form a displacement restricting part 6, respectively, and the side frames 1 and 19 restrict the heating element 3 from being displaced in the front direction. You can also Therefore, the side frames 1 and 19 can also support the heating element 3 in the front direction.

  Therefore, according to the electric heater 2, the number of parts can be reduced, and the heating element 3 can be stably supported by the side frames 1 and 19.

Further, in the electric heater 2 of this example, the electrode plate 31 is used for energizing the heating element 330. The electrode plate 31 has a terminal portion 311 protruding from the side surface of the heating element 3. The terminal portion 311 is connected to an external power source or the like, and is necessary for heat generation of the heating element 330 via the terminal portion 311. Electric power is supplied (see Example 1).
In the electric heater 2 of this example, a slit 100 is provided in the side frame 1, and the heating element 3 is inserted into the slit 100 from its side surface 304. When the heating element 3 is inserted into the slit 100, the terminal portion 311 of the electrode plate 31 protruding from the side surface 304 of the heating element 3 is inserted into the slit 100.
Therefore, the terminal portion 311 of the electrode plate 31 can be protruded to the side of the side frame 1, that is, to the side of the electric heater 2 while being inserted through the slit 100. Therefore, the terminal part 311 in the electrode plate 31 can be arrange | positioned using the inside of the slit 100, and the electric heater 2 can be comprised compactly.

(Example 2)
This example is an example which shows the other variation of the said displacement control part 6, as shown in FIGS.
That is, as shown in FIGS. 12 to 15, the holding tool 33 in the heating element 3 of this example has a holding recess 34 for holding the side frames 1 and 19 in the front direction at the side end portions on both sides thereof. Respectively.
And the shift | offset | difference regulation part 6 of this example is each formed in the side edge part of the both sides of the holder 33, and each side frame 1 and 19 is each set to each holding | maintenance recessed part 34 from each side of the holder 33, respectively. It is formed by inserting.
Further, each side frame 1, 19 in this example does not have the slit 100. Therefore, in this example, the width in the front direction of each side frame 1, 19 can be reduced, and the width in the front direction of the heating element 3 can be reduced.

As shown in FIGS. 12 and 14, the heating element 3 of this example is formed by stacking a plurality of heating units 30 in which heating fins 32, electrode plates 31, and holders 33 are stacked. Specifically, the heating element 3 of this example is formed by stacking the heating units 30 in five stages.
And the heat generating body 3 inserts and arrange | positions the main-body part 10 of each side frame 1 and 19 to the holding | maintenance recessed part 34 of each holder 33, and a pair of fixing pieces 11 and 12 of each side frame 1 and 19 are the 1st. The heating units 30 are integrated by energizing the stacked state of the heat generating units 30 via the first and second holding frames 21 and 22.
12 shows a state in which the side frame 1 is inserted and arranged in the holding recess 34 of each holder 33, and FIG. 13 shows a state before the side frame 1 is inserted and arranged in the holding recess 34 of each holder 33. Indicates the state.

In this example, as shown in FIGS. 12 and 16, the bottom surface 341 of the holding recess 34 of each holder 33 faces the side frames 1 and 19 from the side, and the holding recess 34 of each holder 33. A pair of inner wall surfaces 342 face the side frames 1 and 19 from the front direction.
Thereby, each side frame 1 and 19 can also support the heat generating body 3 from the side, press it in the lamination direction, and can also support it stably also in a front direction.

  Further, as shown in FIG. 15, each holding tool 33 has holding grooves 35 on both surfaces in the stacking direction, and the end portions of the heat generating fins 32 and the holding grooves 35 on one side (upper side in this example) The electrode plate 31 is held, and the end of the other heat generating fin 32 is held in the holding groove 35 on the other side (lower side in this example). Each holding groove 35 is formed by a pair of wall portions 351 protruding in the stacking direction of the heating elements 3 and a plate portion 350 that bridges between the pair of wall portions 351.

As shown in FIGS. 12 and 16, a notch portion 352 for inserting and arranging the terminal portion 311 of the electrode plate 31 is formed in a part of the wall portion 351 forming the upper holding groove 35. In addition, the electrode plate 31 of this example has a terminal portion 311 that protrudes in the front direction of the holder 33. The terminal portion 311 is inserted into the notch 352 and protrudes in the front direction of the holder 33.
The electrode plate 31 of this example has a substantially flat plate shape, and the main body plate 312 and the terminal portion 311 form substantially the same surface. The terminal portion 311 is bent with respect to the main body plate 312 so as to protrude in the front direction of the holder 33, and forms an L shape together with the main body plate 312.
Thereby, the terminal part 311 of the electrode plate 31 can be taken out in the front direction, and the terminal part 311 can be taken out appropriately even when there is a space restriction on the side (lateral direction) of the heating element 3. In addition, the lateral dimension of the electric heater 2 can be reduced.

Moreover, the terminal part 311 of the electrode plate 31 can also be made into the following shapes.
That is, as shown in FIGS. 17 to 19, the terminal portion 311 of the electrode plate 31 can be formed so as to stand substantially perpendicular to the main body plate 312. In this case, the terminal portion 311 standing in a substantially right angle can be projected in the front direction of the holder 33. In this case, the length of the terminal portion 311 in the horizontal direction can be reduced, and the space occupied by the terminal portion 311 in the horizontal direction can be reduced.
In addition, in this example, it is the same as that of the said Example 1, and the effect similar to the said Example 1 can be acquired.

FIG. 3 is a perspective development view of the electric heater according to the first embodiment. 1 is a plan view of an electric heater according to Embodiment 1. FIG. 1 is a schematic diagram of a heating element according to Example 1. FIG. The perspective view of the side part frame concerning Example 1. FIG. Explanatory drawing which shows the state concerning Example 1 which fixed the side part frame from the side surface of the heat generating body. Explanatory drawing of a holder and heat generating element concerning Example 1. FIG. The top view of the holder concerning Example 1. FIG. Sectional drawing of the holder concerning Example 1. FIG. FIG. 3 is a perspective explanatory view of a first insulator according to the first embodiment. Explanatory drawing of the side surface of the heat generating body before providing the side part frame concerning Example 1. FIG. Explanatory drawing of the side surface of the heat generating body which provided the side part frame concerning Example 1. FIG. Explanatory drawing of the side surface of the heat generating body before providing the side part frame concerning Example 2. FIG. Explanatory drawing of the side surface of the heat generating body which provided the side part frame concerning Example 2. FIG. The top view of the electric heater concerning Example 2. FIG. Sectional explanatory drawing of the heat generating body lamination direction of the electric heater concerning Example 2. FIG. Explanatory drawing which shows the terminal part of the electrode plate concerning Example 2. FIG. Explanatory drawing of the side surface of the other heat generating body which provided the side part frame concerning Example 2. FIG. Explanatory drawing which shows the terminal part of the other electrode plate concerning Example 2. FIG. The perspective view which shows the terminal part of the other electrode board concerning Example 2. FIG. Explanatory drawing of an electric heater concerning the past.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Side part frame 10 Support part 11 1st fixed piece 12 2nd fixed piece 2 Electric heater 21 1st holding frame 22 2nd holding frame 3 Heating element 31 Electrode plate 32 Radiation fin 33 Holding tool 330 Heating element 34 Holding recessed part 6 Deviation regulation department

Claims (5)

A heating element having a heat dissipating fin, a heat generating element that generates heat when energized, a holder that holds the heat generating element, and an electrode plate that supplies power to the heat generating element are stacked, and the medium to be heated is in the vicinity of the heat dissipating fin An electric heater passing through
The electric heater has first and second holding frames on both end surfaces of the heating element in the stacking direction, and side frames on both side faces of the heating element,
The side frame includes a support portion disposed on a side surface of the heating element, and a pair of fixing pieces that are formed at both ends of the support portion and press the heating element in the stacking direction.
The electric heater, wherein the heat generating element and the side frame are engaged with each other to form a displacement restricting part that restricts the positional deviation of the heat generating element in the front direction.   In Claim 1, the said side part frame has the slit which is a through-hole along the side surface of the said heat generating body, The said displacement control part is formed by inserting the said heat generating body in this slit. An electric heater characterized by that.   3. The electric type according to claim 2, wherein the holder of the heating element includes a main body portion that holds the heat generating element, and a terminal protruding portion that is narrower than the main body portion and is inserted into the slit. heater. In Claim 1, the holder in the heating element has a holding recess for holding the side frame in the front direction,
The electric heater according to claim 1, wherein the side frame forms the displacement regulating portion by being inserted into the holding recess from a side surface of the holder.   The electric heater according to claim 1, wherein the side frame is made of an elastic metal material.

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