KR970002887Y1 - Positive temperature coefficient thermistor device - Google Patents

Abstract

None.

Description

Static thermistor device

1 is a cross-sectional view of an essential part in a basic embodiment of a static thermistor device according to the present invention.

2 is an exploded perspective view of the apparatus shown in FIG.

3 is a cross-sectional view of an essential part of a typical example of a conventional static thermistor device.

4 is an explanatory diagram of an unreasonable state that may occur in the static thermistor device shown in FIG.

* Explanation of symbols for the main parts of the drawings

1, 1 ': static thermistor element 2: common electrode plate

3: individual electrode plate 4: insulated case

5, 5 ': side wall surface portion 6: ceiling plate portion to upper lid

7: elastic contact means 8: bottom wall portion

20, 30: groove

21-1, 21-2, 31-1, 31-2, 31-3, 31-4: each tapered surface formed by each recess

P1, P2, P3: contact point with each tapered surface at the peripheral edge of one main surface of each static thermistor element

The present invention relates to a so-called double element type static thermistor device in which a pair of static thermistor elements are enclosed in an insulation case, and more particularly, to an improvement in the supporting structure of each static thermistor element in an insulation case. .

As described above, the double element type static thermistor device can be used for heating and one side of a pair of static thermistor elements incorporated in an insulating case, for example, for automatic element circuits of color televisions. However, the physical cross-sectional structure of a representative article specifically provided as a product is as shown in FIG. 3 (see, for example, Japanese Patent Laid-Open Nos. 60-25205 and 60-259076).

Next, this will be described as a conventional example, but in this case, the second diagram showing an embodiment of the present invention in an exploded perspective view can also be referred to as appropriate.

It is because the same structure as the conventional example described here is shown in FIG. 2 except the improvement part by this invention mentioned later.

In the static characteristic thermistor device shown in FIG. 3, there is an insulating case (resin case, etc.) 4 in which the inner hollow part is closed by the ceiling plate part or the upper lid 6, and therein a pair of static thermistor elements. (1,1) is piled up and stored.

The insulating case 4 usually has a footnote formation or a box shape, and each of the characteristic thermistor elements 1 and 1 has a disc shape of a moderate thickness, and is not shown in detail, but the terminal electrode faces on both sides of its front and back sides. There is this.

The common electrode plate 2 is inserted between the pair of static thermistor elements 1 and 1 in the case 4, and the positive electrode thermistor elements 1 and 1 are connected to the common electrode plate 2. The main surfaces or terminal electrode surfaces facing each other are commonly electrically connected.

On the other hand, each of the terminal electrode surfaces of each of the static thermistor elements 1 and 1 is respectively formed in accordance with the inner surface of the pair of case side wall surface portions 5 and 5 facing each other among the four side wall surface portions of the insulating case 4. The elastic contact means 7 and 7 respectively attached to the pair of individual electrode plates 3 and 3 provided are press-contacted.

As shown in the drawing, the elastic contact means 7 and 7 have a shape in which only one of them is supported, and is an electrically conductive plate spring contact having elasticity, but this corresponds to the corresponding characteristics of the respective thermistor elements 1 and 1. In order to ensure the electrical connection between the terminal electrode surface and each of the individual electrode plates 3 and 3, and to stably maintain the overlapping state of the positive characteristic thermistor elements 1 and 1 in the case 4. .

Therefore, in order to enhance this function in the prior art, for each of these individual electrode plates 3, 3, the number of contacts constituting the elastic contact means 7, 7, is increased, respectively, for example, as shown in FIG. In some cases, they may be paired together.

The common electrode plate 2 or the individual electrode plates 3 and 3 are slits 9:10 and 10 respectively drilled in the bottom wall 8 of the case 4 corresponding to their arrangement positions (see Fig. 2). It inserts a narrow portion inside and further protrudes its tip portions 2 ': 3', 3 'out of the case, and its tip portions 2': 3 ', 3' are very thin so that the printed wiring board It is attached to (not shown).

In addition, after storing the thin portion of each electrode plate (2: 3, 3) so as to penetrate into the corresponding slits (9:10, 10) from the inside of the case, it is unavoidable to escape after that. In the thin portion of each electrode plate (2: 3, 3), the elastic sheet for papermaking (11:12, 12) etc. to be fitted to the outer surface of the back surface of the case bottom wall part 8, etc. are provided in the narrow part of width | variety so that it may be removed. .

The conventional double element type static thermistor device has a structure as described above, but the object of the present invention is to cover the overlapping state of a pair of static thermistor elements 1 and 1 in the insulating case 4. Means to maintain.

On the other hand, in the related art, as described above, a pair of elastic contact means 7 and 7 is used, and a pair of static thermistor elements 1 and 1 are pressed from both sides by the spring elasticity thereof.

However, under various circumstances ranging from the manufacturing process of the static characteristic thermistor device to the assembling process to the actual use state, as described above, only the force pushed by the pair of elastic contact means 7 and 7 can be used. The superposition state between the characteristic thermistor elements 1, 1 may not be maintained.

In fact, when a large vibration or shock is applied from the outside, even if the elastic contact means 7 is pressed against the common electrode plate 2, respectively, the elastic contact means 7 is the main surface of the static thermistor element 1. Since it is only in point contact in the vicinity of the center of the image, as shown in FIG. 4, even if the positive thermistor element 1 is inclined inside the case or not, the direction is orthogonal to the ground in FIG. 4 along the common electrode plate 2 You can tilt sideways.

In this case, as can be seen in the above-described automatic element circuit, the use of one of the pair of static thermistor elements 1.1 such as the heating side and the other side of the heat receiving side, that is, the heat between the two In applications where coupling is very important, the thermal coupling degree greatly deviates from the design estimate value or the required value, and the electrical characteristics of the circuit system using this as well as the static characteristic thermistor device alone deviate considerably from the expected value.

Further, since the inclination of the static thermistor element as shown in FIG. 4 may also occur in the assembling process when storing it in the insulating case, care must be taken in its insertion work, and therefore workability is not efficient.

In fact, such an inclination of the device is more likely to occur than the inclination of the side as described above, and such inclination is likely to increase the variation of thermal and electrical characteristics.

The present invention has been made to solve the above problems, and is a double element type static thermistor device as described above, and has a structure that can stably maintain a pair of static thermistor elements housed in an insulation case in a normal superposition state. To try to start.

In order to solve the above problems, in the present invention, the double element type static thermistor device, namely

Ⓐ: has an insulating case having a side wall portion enclosed around the inner hollow portion, a ceiling plate portion and a bottom wall portion covering the upper and lower portions of the inner hollow portion, and in the inner hollow portion of the insulating case, The common electrode plate is sandwiched between the pair of plate-shaped positive characteristics thermistor elements to be overlapped, and the pair of overlapped positive characteristics thermistor elements are stored in a state of being pushed into the pair of elastic contact means from both sides thereof, and the common In a static thermistor apparatus in which a part of an electrode plate and a part of each individual electrode plate each having the pair of elastic contact means are projected out of the insulating case, and each of the protruding portions is an electrical connection portion with an external circuit. After improving, we again propose a static thermistor device with the following phrases ⓑ to ⓓ.

Ⓑ is the same on the inner surface of the ceiling plate and the bottom wall of the insulating case The unit is installed.

Ⓒ: each of these The portion forms at least a pair of tapered surfaces inclined from a position close to each individual electrode plate located along the inner surface of the side wall portion of the insulating case toward a position where the common electrode plate is located near the center.

Ⓓ: The peripheral edges of the main surfaces of the pair of positive characteristics thermistor elements superposed on each other as described above, respectively, on the elastic contact means side (individual electrode plate side), respectively In contact with each one of the at least one tapered surface which forms a part at least 1 point or more, respectively.

This is a static thermistor device having a basic configuration according to the present invention. However, in the present invention, when the insulating case forms a footnote phenomenon of the internal hollow, the side wall portions are configured such that four adjacent sidewall portions are orthogonal to each other. Therefore, in view of a pair of side wall surface portions orthogonal to the side wall surface portion adjacent to the pair of individual electrode plates, the inner surface of each of the pair of side wall surface portions is replaced with the ceiling plate portion and the bottom wall portion. The structure which forms one junction of the recessed part is also disclosed.

In addition, the present invention provides a total of two grooves disposed in each of the ceiling plate portion and the bottom wall portion, or one pair of opposing side wall surface portions. Part), and even one of the preferred shapes is disclosed as one embodiment thereof.

That is,

Ⓔ: One side of the groove is formed into a V-shape to form a pair of tapered surfaces; The other recessed portion fits one diagonal line at the bottom in the direction of the distance between the pair of individual electrode plates, and causes the vertices to dig into a quadrangular pyramidal shape below or near the common electrode plate, thereby providing each static thermistor. Forming four tapered surfaces in total, two toward the element; Is an additional component requirement.

Therefore, the present invention is also applicable to, for example, a square plate-shaped static thermistor element whose main surface is spherical, as described in the following section, but in the case of using a disc-shaped static thermistor element as a more general form. In view of the diameter thereof, the degree of indentation or the inclination of the tapered surface is appropriately designed in consideration of the diameter thereof.

Ⓕ: The contact at the peripheral edge of the circumferential surface of the disk-shaped static characteristic thermistor element with respect to each corresponding tapered surface having a pair of tapered surfaces curved in a V shape is point contact at one point, The contact at each circumferential edge of each of the two tapered surfaces of the curved groove having four tapered surfaces having a total of four tapered surfaces is point contact at two points in total, one point on the two tapered surfaces. that; We also propose an additional configuration requirement.

According to the present invention, two surface portions of each wall surface portion constituting the insulating case, which face each other in a direction orthogonal to each thickness direction (their overlapping direction) of a pair of static thermistor elements, that is, the ceiling plate portion and Grooves for forming at least one pair of tapered surfaces are provided on each inner surface of the pair of side wall surface portions on which the bottom wall portion or each elastic contact means is not disposed, and each of the positive characteristic thermistor elements Since the circumferential edge portion of the main surface on the side of the elastic contact means is in contact with each corresponding tapered surface with at least one point or more, this contact portion can provide a physical resistance (regulatory force) against the inclination of each static thermistor element. .

In other words, each static thermistor element, even if inclined, is supported by only one side of the tapered surfaces facing each other at least at two points facing each other from the peripheral edge of one main surface thereof, and moving in the direction away from each other in the superimposition direction. This is regulated and does not tilt.

This action is naturally obtained even when the expression of at least two is defined in the present invention, even if each of the tapered surface forming recesses forms a V shape, and only two tapered surfaces are formed as the minimum number required. Not only the regulating force for tilting but also the frictional force due to the contact between each major surface portion of each static thermistor element and the corresponding tapered surface, the prevention effect of tilting due to the common electrode plate is also obtained. have.

Moreover, according to one aspect of the present invention, The part is bent in a V-shape, so that only two tapered surfaces are formed, but the other tapered surface forming recess is curved in a quadrangular shape, and in the case of having four tapered surfaces in total, tilting and misalignment are prevented together. .

In this description, the shape of the static thermistor element to be used is generally disk-shaped, and each main surface has a circular planar shape. If so, it is almost the same.

That is, when the main surface of the static thermistor element has a spherical phenomenon, the main surface of each static thermistor element is a tapered surface which is one of the inclined surfaces of one pair of tapered surfaces of the recessed portion bent in the kanji shape at one side thereof. Of the two tapered faces on each of the static thermistor elements of the four tapered faces of the four-cornered recessed portion are in contact with each other, and the opposite end portions of the edge facing the Han Chinese edge face each other. The contact portion with the tapered surface is formed by two points on one side and the edge facing the one side, that is, one point of "three-point contact" becomes a stable type converted into line contact, so that it does not tilt or shift. do.

On the other hand, when the main surface shape of each static thermistor element is a general circular shape, what is necessary is just to think that one side part which faces the taper surface which is one inclined surface among the pair of the taper surfaces of the said recessed-curved V-shape is one point. In this case, a three-point support structure can be provided, which can also reasonably prevent inclination or misalignment.

As a matter of course, the grooves for forming the tapered surface are formed together with the four-corner grooves, so that the structure having four or more points of support for each of the static thermistor elements as a whole may be obtained.

In addition, as shown on the gist configuration of the present invention, the above operation is, of course, in the case where the respective recesses are provided on the top plate and the bottom wall of the insulating case, instead of them, the upper surface of which the elastic contact means is in contact with each other. The same applies to the case where the respective grooves are provided on each inner surface of the pair of side wall surface portions orthogonal to the side wall surface portion.

EXAMPLE

Hereinafter, one preferred embodiment of the present invention will be described with reference to FIGS. 1 and 2, but for convenience of comparison with the conventional example shown in FIG. The same reference numerals are given to those used for the conventional examples, and the same configurations are used.

Therefore, in this embodiment as well, the insulating case 4 such as a resin case having a hollow portion therein is formed into a box shape or a footnote shape, and the four side wall surface portions 5 and 5 that are orthogonal to each other are adjacent to each other: 5 ') has a side wall portion, a bottom wall portion 8 which disintegrates under the inner hollow portion, and a ceiling plate portion to an upper lid 6 covering the upper portion.

In particular, in the insulating case 4 used in this embodiment, four side wall surface portions 5 and 5: 5 'and 5' and the bottom wall portion 8 are formed integrally with the resin in advance. Only the lid to the ceiling plate part 6 are formed separately, and after storing the static thermistor elements 1 and 1 and the respective electrode plates 2: 3 and 3 as described later, The fitting projections 13 and 13 formed on the pair of side edges facing the ceiling plate portion 6 are fitted on the upper side of the pair of side wall surface portions 5 'and 5' corresponding to the case side wall portions. The inside of the case is closed by inserting into the fitting grooves 14 and 14. Moreover, these fitting projections 13 and 13 and corresponding fitting grooves 14 and 14 are shown only in each of them in FIG.

However, such a case assembly method itself is arbitrary rather than the present invention directly defines this.

The pair of static thermistor elements 1 and 1 are accommodated in the inner hollow portion of the insulating case 4 in a superposed state, but the common electrode plate 2 is sandwiched therebetween.

Although not shown in detail, the common electrode plate 2 is provided on both the front and back surfaces of the static thermistor elements 1 and 1 as the main surface itself or as a conductive surface formed separately on the main surface. The pair of static thermistor elements 1 and 1 are electrically connected in common to the terminal electrode surfaces facing each other.

On the other hand, on the other terminal electrode of each static thermistor element 1, 1, that is, the terminal electrode surface on the main surface side which is oriented in the superimposition direction, a pair of opposite side walls 5, 5 facing in the insulating case 4 The elastic contact means 7 and 7 attached to the individual electrode plates 3 and 3 respectively arranged along the inner side of the c) are bonded to each other.

When the elastic contact means 7 and 7 are shown in figure, they consist of a pair of leaf | plate spring contacts formed in the parallel shape by press-cutting formation etc., respectively, The action is as having already described regarding the prior art example, and each static characteristic The electrical contact with the corresponding terminal electrode surfaces of the thermistor elements 1 and 1 is assured, and the overlap state of the pair of static thermistor elements 1 and 1 into which the common electrode plate 2 is inserted is stabilized to some extent. Has an operation to do.

Conversely, the shape or configuration thereof is not limited to the leaf spring shape as shown as long as it has this action. In addition, the present invention has no direct relation, but as can be seen from the leaf spring contact, when a contact means having a small contact area with respect to the terminal electrode surface of the corresponding static characteristics thermistor element is used, the outside of the case of each electrode plate described later There is also an operation for reducing or suppressing undesirable heat conduction to the electrical circuits which are in electrical or physical contact with the protruding tip portions of the heat sinks, and further to the external circuits through the wiring lines.

The common electrode plate 2 protrudes to the outside through the slits 9 through which a narrow portion thereof is formed in the insulating case 4 and the bottom wall portion 8, and the tip portion 2 ′ of the common electrode plate 2 is printed. It penetrates further through transparent holes arranged at a predetermined point on a wiring board (not shown), and is further sharpened to facilitate electrical contact through soldering or the like on a predetermined conductive pattern provided on the surface side.

In exactly the same manner, the narrow portions of the individual electrode plates 3 and 3 serving as the dedicated electrodes for the respective thermistor elements 1 and 1 are also formed on the side edges of the bottom wall 8. It protrudes to the outside through 10 and 10, and its front end parts 3 'and 3' can be used as an electrical connection part to an external circuit.

Furthermore, in the case of this embodiment, the respective electrode plates 2; 3, 3 have their tip portions in their corresponding slits 9; 10, 10 from the inside of the case, as in FIG. 2 in the actual assembly. 2 '; 3'; 3 ') is inserted, and further the narrow part is pushed back to the case. However, at this time, the elastic tongues 11, 12, 12) pass through the inside of each slit (9; 10, 10) while being bent, and then elastically restores from the exit of the slit so as to be bitten on the outer surface of the rear surface of the bottom wall (8) to prevent it from falling out. Can be. However, the present invention is also not essential for the present invention. In some cases, the portions 2 ', 3', 3 'protruding to the outside of each terminal electrode plate 2; 3, 3 are not the bottom wall portion 8; Even if it protrudes through any suitable part of the side wall surface part (for example, the side wall surface parts 5 'and 5' orthogonal to the side wall surface parts 5 and 5 which the individual electrode plates 3 and 3 contact | connect) among several side wall surface parts. good.

Therefore, even in the illustrated apparatus shown in the drawing, the components up to this point are those which do not particularly require modification in the conventional static thermistor apparatus.

Since this embodiment is in accordance with the present invention, the newly-noted characteristic components that are not conventionally provided are in each of the ceiling plate part to the upper lid 6 and the bottom wall part 8, and can be recognized in the inner part towards the inner hollow part of the case. Can be.

First, although it is displayed in an inverted state in FIG. 2, a V-shaped groove 20 is formed on the inner surface of the ceiling plate part 6, and the surface portions 21-1 corresponding to the respective leg portions of the V-shape are formed. 21-2) has a tapered surface, respectively.

As shown in FIG. 1, the inclination directions of the pair of tapered surfaces 21-1 and 21-2 are as shown in FIG. 1, and in the assembled state, the common electrode plates ( 2) It is inclined upwards towards the position.

Therefore, in the case of the V-shaped groove portion 20 having the pair of tapered surfaces as the groove portion formed in the ceiling plate portion 6, the groove portion 20 is located at or near the common electrode plate 2. It is manufactured to come in the V-curved part.

On the other hand, although the groove portion 30 is formed on the surface facing the inside of the case, that is, the upper surface of the bottom wall portion 8, in the present embodiment, the groove portion 30 formed on the inner surface of the bottom wall portion 8 is a four-corner weight. The convex projections are formed to be bent, and thus the concave grooves 30 themselves are also quadrangular in shape.

As a result, all four tapered surfaces 31-1,31-2: 31-3,31-4 are formed as a tapered surface, but the recessed part 30 is also one in the bottom surface of its four-corner weight. The diagonal of is fitted in the direction of the distance between the pair of individual electrode plates (3,3) (so another diagonal line is parallel to each individual electrode plate (3,3)). The apex is formed below or in the vicinity of the common electrode plate 2.

If this is described with respect to each tapered surface 31-1,31-2: 31-3,31-4, each tapered surface 31-1,31-2: 31-3,31-4 will have a triangular shape, respectively. One side of this triangle is placed on the inclined position connecting the middle of each of the two circumferential edge portions orthogonal to the bottom wall portion 8 on the surface of the bottom wall portion 8, and the vertices at which the other two sides are orthogonal are low. It is set as the inclined surface of the downward gradient located on the perpendicular | vertical line which passes through the center point which a diagonal line of the wall part 8 cross | intersects, or a center point.

Thus, in the insulating case 4 in which the recessed part 30 is provided in the bottom wall part 8, as described above, a pair of static thermistor elements 1 which were polymerized by sandwiching the common electrode plate 2 therebetween. When the elastic contact means (7, 7) of the pair of individual electrode plates (3, 3) are inserted into both sides again, and (1), and then the ceiling part 6 having the recesses 20 is covered and fixed. , Its cross-sectional structure is the same as in FIG.

What is important here is that each of the pair of static thermistor thermostats (1, 1) is individually separated for each tapered surface formed by the recesses (20, 30) provided in the ceiling (6) and the bottom wall (8). The main surface on the electrode plate side is in contact with each other at its peripheral edge. Conversely, in order to satisfy such a relationship, each dimension factor such as the thickness of the ceiling plate portion 6 or the bottom wall portion 8, the depth of each groove portion 20, 30, the dimension of each tapered surface, or the inclination of each tapered surface is used. Design is made according to the diameter and thickness of the static thermistor elements (1, 1).

Examining this contact relationship in more detail, since the static thermistor elements 1 and 1 used in this embodiment have a disc shape, the individual electrode plate side of the static thermistor element 1 located on the right side and the front side in FIG. Among the three points P1, P2, and P3 attached to the upper periphery of the main surface, the point P1, which is the highest position point in the height direction when accommodated in the insulating case 4, is first shown in FIG. As shown, the pair of tapered surfaces 21-1 and 21-formed by the grooves 20 of the V-shape (which may be referred to as a stake type in the attached state) provided on the ceiling plate part 6 may be referred to as a downward shape. 1) Point contact is made at a point in the middle of the tapered surface 21-1 on the right side.

On the other hand, in FIG. 2, the remaining two points P1 and P3 shown in the peripheral edges of the individual electrode promotion surfaces of the positive characteristic thermistor element 1 on the right side are recess portions provided in the bottom wall portion 8, respectively. Of the four tapered surfaces of (30), point contact is made with respect to each of the right static thermistor elements 1 and the two tapered surfaces 31-1 and 31-2 located at one point.

In FIG. 1, the state in which only the point P3 of the two points P2 and P3 is in contact with one of the tapered surfaces 31-2 is also shown because of the cross-sectional structure.

Similarly, the left side of the positive characteristic thermistor element 1 can be said, and the three points which are surface symmetric with respect to the surface containing the said three points P1, P2, P3 and the common electrode plate 2 (to be simplified) For this left element, a sign is not attached to these points), and the upper one point is in point contact with another tapered surface 21-2 on the ceiling plate portion 1 side, and the remaining two points are Is in point contact with each of the remaining two tapered surfaces 31-3 and 31-4 of the bottom wall portion 8.

Therefore, a so-called three-point support structure is formed for each of the static thermistor elements 1, and each tapered surface is inclined in a direction to push each of the static thermistor elements 1 and 1 toward the other side, so that the present apparatus Even if vibrations or shocks are applied from the outside, movement of the pair of static thermistor elements 1 and 1 in a direction away from each other is suppressed, and the inclination of the element as described with reference to FIG. Can be effectively prevented.

In other words, these three-point support structures also have a positioning action of each of the static thermistor elements 1 and 1 in the insulator case 4, so that each of the elements 1 and 1 is inserted into the insulation case. This is facilitated.

In addition, since it means that the whole characteristic thermistor elements 1 and 1 cannot contact other parts of an insulation case except three points, when heat generation is anticipated in the element itself like the above-mentioned automatic element circuit, The heat transfer may be prevented from being transmitted to the insulating case as much as possible, and the heat dissipation may be even.

When the vibrations or shocks are applied as in the prior art, under the condition that each of the static characteristic thermistor elements can come into contact with a different position at the time on the inner surface of the insulating case, the heat dissipation relationship at that time varies, and It causes a misalignment.

The groove structure to the tapered surface formation structure shown in FIG. 1 and FIG. 2 is, for example, the surface of the groove to taper surface even if each of the static thermistor elements 1 and 1 is changed into a plate shape. You can cope with this by making design changes in. That is, this can be easily understood by considering the element 1 'as shown by the spherical line of the virtual line in FIG.

This static thermistor element 1 'has the edge located at the top of the four edge portions of the peripheral edge of the main surface on the side of the individual electrode plate passing through the point P1 described above, and thus, the ceiling plate portion 6 The point contact can be made in line contact with one of the tapered surfaces 21-1 of the recess 20 provided.

On the other hand, both end portions P2 and P3 of the edge portion facing the edge portion are set to the points P2 and P3 described above with respect to the disc shaped element 1, and therefore, these advantages are provided in the bottom wall portion 8. The middle of the four tapered surfaces of the recessed portion 30 is in point contact with the two tapered surfaces 31-1 and 31-2 located on the element side as described above.

Therefore, as is apparent, even when this rectangular plate-like element 1 'is used, three points on the element 1' are based on the tapered surface structures of the upper and lower groove portions 20 and 30. As a modification of the support structure, there is provided a support structure in which one point is changed to linear contact, and likewise, their plate-shaped static thermistor elements 1 ', 1' can be protected from movement in a direction insulated from each other, Alternatively, positioning in these insulating cases can be achieved.

As mentioned above, although the embodiment shown in figure was demonstrated, as an improvement modified example, each shape of the recessed part 20 and the recessed part 30 can be mutually replaced. That is, the recessed part 20 of the ceiling plate part may be quadrangular, and the recessed part 30 of the bottom wall part side may be V-shaped.

In addition, a four-cornered groove can also be formed on the ceiling plate portion 6 side and the bottom wall portion 8 side, and in this case, a more stable support structure of four points or more can be obtained.

On the contrary, compared with the conventional example without the idea of the tapered surface structure, even if only the V-shaped grooves 20 are provided on the ceiling plate portion 6 side and the bottom wall portion 8 side, for example, sufficient effects are obtained. You can get it.

That is, in the above description, if the static thermistor elements 1 and 1 are circular, the same point in which the additional point opposite to the point P1 in contact with the tapered surface of the ceiling plate part in the radial direction is provided on the bottom wall side side. Although it is point-contacted to the corresponding taper surface of a V-shaped groove part, and becomes two point support which opposes in the element radial direction as a whole, it can be said that the inclination of the element itself can still be fully suppressed.

In this case, however, the inclination along the common electrode plate 2 and the inclination in the direction orthogonal to the inclination state as shown in FIG. As long as the idea of making contact abuts, any suitable setting of the relation of relations, by their joint frictional force, can show a certain degree of resistance to movement in such a direction. As it is also indicated by the static thermistor elements 1 'and 1', in the case of a rectangular plate shape, the two-point contact is changed to two line contacts, so that the inclination in any direction can be suppressed.

Furthermore, the above-described bar has been described only in the case where the pair of grooves 20 and 30 are provided in the ceiling plate portion 6 and the bottom wall portion 8, but instead of each of the individual electrode plates 3 and 3, respectively. The grooves 20 and 30 may be provided in one of the pair of side wall surface portions 5 'and 5' orthogonal to each of the side wall surface portions 5 and 5 in contact with each other. The cross-sectional view is well understood (ignoring the extraction direction of each electrode plate), and in this case, the above description can be applied almost as it is.

Further, in consideration of actual assembling, when the side wall portions 5 'and 5' are provided with respective tapered surface structures, each electrode plate is polymerized in a state in which a pair of static thermistor elements 1 and 1 are polymerized. When (2, 3, 3) is inserted into the inner hollow part of the insulation case 4 together, when one recessed part (for example, the recessed part 30) is a four-corner shape, it becomes a slightly unreasonable insertion work. However, this also exhibits appropriate elasticity depending on the material of the insulating case 4, and is not impossible at all, but can be sufficiently realized.

Of course, there is no problem if one of the side wall portions 5 'and 5' is made to have a case structure such as to be attached last.

In addition, although the groove part was formed directly in the sphere itself of the ceiling plate part 6 and the bottom wall part 8 in the case of illustration, the plate for groove part formation is provided separately, respectively, and they are respectively the ceiling plate part 6 and the low. You may provide along the inner surface of the wall part 8.

This can also be said in the case where these recessed portions are arranged in the side wall portions 5 ', 5' instead of the ceiling plate portion 6 or the bottom wall portion as described above.

Also for the insulating case 4, for example, a cylindrical case or the like may be used instead of the illustrated footnote or box shape. Although not only the outer shape but also the inner hollow part is cylindrical, a structure for supporting the pair of individual electrode plates 3 and 3 oppositely can be easily obtained, and even if the ceiling plate part and the bottom wall part are circular, the tapered surface according to the present invention Grooves forming the groove can of course be installed on its inner surface.

According to the present invention, in the static thermistor device adopting a so-called double element structure, the position shift or the inclination between a pair of static thermistor elements embedded in the insulating case can be effectively suppressed, and the thermal coupling state between each electrode and each electrode The electrical contact relation to the plate can be greatly stabilized, and the positioning effect of each static thermistor element in the insulating case can also be obtained.

In other words, the impact resistance and vibration resistance can be improved, and ultimately, the thermal and electrical characteristics can be stabilized, or the occurrence of contact failure can be suppressed or the thermal deflection relation can be uniform. The characteristics can be easily managed, and the design freedom and reliability of the circuit system using the apparatus as well as the static characteristic thermistor apparatus alone are increased.

Nevertheless, the physical structure required thereby is extremely simple, so that productivity is not impaired at all, and conversely, workability is improved. It is because the effect which makes positioning of each static thermistor element easy by the tapered surface structure can also be anticipated.

In addition, a structure in which each static thermistor element does not come into contact with the inner surface portion of the insulating case can be obtained except for a portion having almost no area such as each tapered surface and a point contact portion or a line contact portion. By stabilizing, uniformity of characteristics can also be obtained.

Claims (5)

An insulating case having a side wall portion surrounding the inner hollow portion, a ceiling plate portion and a bottom wall portion covering the upper and lower portions of the inner hollow portion, and a plate-shaped static thermistor element having both front and back surfaces in the inner hollow portion of the insulating case. The common electrode plate is sandwiched between the pair of electrodes, and the pair of overlapping static thermistor elements are stored in the state of being pressed together by the elastic contact means of the pair of individual electrode plates provided along the inner side surfaces of the opposite side walls on both sides thereof. At the same time, a part of the common electrode plate and a part of the pair of individual electrode plates respectively protrude out of the insulating case, and each of the protruding portions is an electrical connection portion with an external circuit. Among the side wall portion, the top plate portion and the bottom wall portion of the insulating case, the inner surface of the pair of opposing wall portions Similarly, grooves are provided, and each of the grooves forms at least a pair of tapered surfaces inclined from the position close to each individual electrode plate located along the inner surface of the side wall portion of the insulating case toward the position where the common electrode plate is located. The peripheral edges of the main surfaces on the side of the elastic contact means are each of at least one pair of tapered surfaces disposed on the inner surfaces of the ceiling plate portion and the bottom wall of each of the two main surfaces of the pair of the stacked static characteristics thermistor elements. Each one of them is in contact with each other at least one or more points. 2. The pair of opposing walls of claim 1, wherein the insulating case is formed of an inner hollow footnote, and the side wall portion is composed of four side wall surface portions adjacent to each other orthogonal to each other, and a recess is provided on the inner surface. The unit is a static thermistor device, characterized in that the ceiling plate portion and the bottom wall portion. 2. The pair of opposing walls of claim 1, wherein the insulating case has an inner hollow shape, and the side wall portion is composed of four side wall surface portions adjacent to each other orthogonal to each other, and a recess is provided on the inner surface. The part is a pair of side wall surface parts orthogonal to a pair of side wall parts which the said pair of individual electrode plates respectively contact among four side wall surface parts, Thermistor apparatus characterized by the above-mentioned. The groove portion of one of the pair of wall portions is formed by digging a groove in a V-shape to form a pair of tapered surfaces, and the groove portion of the other wall portion of the pair of wall portions. A pair of diagonal lines at the bottom are matched in a distance direction between a pair of individual electrode plates, and grooves are formed by forming a quadrilateral pyramid having the vertices beneath or near the common electrode plate, two on each side of each thermistor element in total. A static thermistor device, characterized by forming two tapers. 4. The respective main surfaces of claim 3, wherein each of the plate-shaped static thermistor elements has a disk shape, and the planar shape of each main surface is circular, and each major surface with respect to each corresponding tapered surface having a pair of tapered surfaces into a V-shape. The contact of the peripheral edge is point contact at one point, while the contact at the peripheral edge of the circumferential surface with respect to the two tapered surfaces of the grooved groove having a four-cornered shape having a total of four tapered surfaces is A static thermistor device, characterized in that a point contact is made at two points in total on one of the two tapered surfaces.