The present invention relates to a temperature switch, and particularly to a temperature switch that is mounted directly on a substrate made of, for example, ceramic or the like.
Traditionally, bimetal temperature switches configured using a ceramic substrate as an insulative support for a thermostat have been proposed. (See, for example, International Patent Application Publication No. WO87/03137)
As shown in
Terminal tabs 3 and 4 are respectively fixed to these metalized longitudinal ends of the support 1.
Each of these terminal tabs 3 and 4 has a hole for soldering on one end, and the other end is divided three portions so as to form a fork shape The end comprises a pair of protrusions 6 on the outer sides, respectively, and a protrusion 7 at the center in such a manner that the pair of protrusions 6 and protrusion 7 great different vertical levels.
The pair of protrusions 6 at the lower level are jointed to the metalized ends on the bottom surface 1a of the support 1. The protrusion 7 that is at the higher level contacts the upper surface of the support 1.
A contact spring 8 has a hole 11 approximately at its center, and a pin 12 made of plastic is inserted into this hole 11. A head 13 of the pin 12 is engaged with the top plane of the contact spring 8, and a lower pole runs through a hole 14 at the center of a bimetal plate 15 and the groove 2 on the support 1.
The bimetal plate 15 is disposed between the support 1 and the spring 8. A collar 16 of the pin 12 is disposed between the contact spring 8 and the bimetal plate 15 in order to serve as a spacer and to provide thermal insulation between the contact spring 8 and the bimetal plate 15.
Also, a film resistor 17 is disposed on the bottom surface 1a of the support 1. This film resistor 17 is electrically connected to the terminal tabs 3 and 4 via conductive strips 18.
When the bimetal plate 15 is inverted in response to a temperature equal to or greater than the switching temperature and lifts the contact spring 8, electric currents flow only through the film resistor 17, while the support 1 is heated and itself heats the bimetal plate 15; thereby the spring prevents the bimetal plate 15 from returning to the original position that closes the switch.
As described above, because the collar 16 of the pin 12 serves as a spacer and provides thermal insulation between the contact spring 8 and the bimetal plate 15, the bimetal plate 15 is hardly affected at all by the Joule heat generated in the contact spring 8.
Additionally, the invention disclosed in the above International Patent Application Publication No. WO87/03137 is based on a concept that a heat source for operating the bimetal temperature switch (referred to as a temperature switch hereinafter) is externally provided (in other words, the temperature switch is operated as a single unit), and this invention employs a configuration for detecting external hot air.
The above conventional temperature switch contains six problems.
The first problem is that the temperature switch employs a configuration to set a special function so that once the status of the switch changes, the switch does not return to the original state when this switch is connected to an external circuit in series. In other words, this switch does not have a common function for opening and closing in accordance with temperature variations.
The second problem is that this temperature switch does not perform heat detection efficiently because this switch has a low responsiveness to heat, and thus reliability is a problem when this switch is used for controlling the temperature of a hot plate heater that is included in, for example, a hair iron or is used for protecting the hot plate heater.
The third problem is that this switch consists of a large number of parts, and for engaging these parts or mounting these parts on the substrate, operations such as welding, soldering, brazing, caulking, rivet caulking, catching, and the like are often required.
Thus, the configurations are complicated, and many steps have to be executed for the assembly.
The fourth problem is that performing caulking requires a highly developed skill because substrates are sometimes broken when performing caulking if the substrates are made of ceramic, leading to a lower yield. However, it is difficult to acquire personnel having such a highly developed skill.
The fifth problem is that the engagement based on catching requires a step of bending an elastic material, and it is impossible to bend an elastic material at a sufficient level so as to cause the catching functions because assembly of the elastic material causes a spring back that is too strong.
The sixth problem is that to form a catching part by bending an elastic material before assembly while also taking the margin of the spring back into consideration requires a step of sliding the catching part of the temperature switch from an end portion to the engagement part in the substrate. This greatly limits the shaping of the substrates and the positioning of engagement parts, thereby decreasing degrees of freedom.
In view of the above problems, it is an object of the present invention to provide a temperature switch that consists of a minimum number of components, that is inexpensive, that is highly responsive to heat detection when being used for a hot plate heater, and that can easily be attached to a substrate made of ceramic or the like.
A temperature switch according to the present invention is a temperature switch having an insulation substrate to which a fixed contact connected to one external terminal is attached, a movable plate that is attached to the insulation substrate, a movable contact at a position facing the fixed contact and that is connected to the other external terminal, and a thermally actuated element that is loosely attached to the movable plate and whose warping direction is inverted at a prescribed temperature for electrically opening and closing a line between one said external terminal and the other said external terminal connected to the fixed contact and the movable contact, wherein:
the movable plate has, on both sides thereof, pawl parts each having a U-shaped cross section with an opening height that catches a side portion thickness of the insulation substrate;
the insulation substrate has, on both sides thereof, cut-out portions that are wider than widths of the pawl parts and deeper than tip lengths of the pawl parts; and
the movable plate catches both side-portions of the insulation plate and is fixed to the insulation substrate by using the pawl parts when the pawl parts are fitted into the cut-out portions and are able to slide in a prescribed pawl width direction.
In one example of the above temperature switch:
the cut-out portion has two steps in a direction from a side portion to a center of the insulation substrate;
the pawl part has a width that is smaller than the width of a second cut-out portion of the insulation substrate having the two steps, has a tip length that is smaller than the depth of the second cut-out portion, and has an opening height that catches a side-portion thickness having a first cut-out portion of the insulation substrate having the two steps; and
the movable plate is positioned with the width-direction-end part at a sliding-direction-downstream side of the pawl part abutting a gap portion between the first cut-out portion and the side portion, and the pawl part catches a side-portion thickness having the first cut-out portion of the insulation substrate and is fixed to the insulation substrate when the pawl part is fit into the second cut-out portion, and the movable part slides in a direction of the first cut-out portion direction.
In another example of the above temperature switch:
the movable plate has an elastic locking part that is adjacent to the pawl part on a sliding-direction-upstream side, has an L-shaped cross section, and has a sponson length smaller than that of the pawl part; and
the entirety of the elastic locking part reversibly warps upward with the L-shaped tip abutting a top surface of the insulation substrate when the pawl part is fitted into the second cut-out portion, and recovers from warping and is positioned with the L-shaped tip overlapping the second cut-out portion and with the width-direction-end part on a sliding-direction-downstream side abutting a gap portion between the first cut-out portion and the second cut-out portion.
In the above case, as one example, it is desirable to employ a configuration in which:
a substrate-thickness having the first cut-out portion of the insulation substrate is formed to be one step smaller than a thickness of substrate main body; and
an opening height of the pawl part of the movable plate is formed to be one step narrower than a thickness of the substrate main body, and is formed to be large enough to catch a substrate thickness having the first cut-out portion. Further, as another example, it is also possible to employ a configuration in which:
the main body of the insulation substrate comprises two insulation substrates consisting of an upper insulation substrate and a lower substrate; and
the first cut-out portion is formed on the upper insulation substrate of the main body.
In the above case, as an example, it is desirable to employ a configuration in which:
in the movable plate, when the pawl parts slide and are engaged with the first cut-out portion of the insulation substrate and an entirety is fixed to the insulation substrate, the pawl parts are set to be further in than the same plane on both side surfaces and a bottom surface of the insulation substrate, respectively.
In the above temperature switch, it is also possible to configure the insulation substrate by using a ceramic substrate including a heater.
An insulative substrate (hereinafter, simply referred to as substrate) 21 shown in
Also, a movable plate 22 shown in
Also,
Also, this movable plate 22 comprises a bimetal that is in the shape of a shallow bowl as a thermally actuated element that is disposed between the above movable and fixation parts and is loosely attached to the movable plate 22.
The bimetal has a heat characteristic in which the direction in which it warps is inverted at a prescribed temperature, and the movable part of the movable plate 22 is caused to move with respect to the substrate 21 in response to the inverting operation of the bimetal; thereby the above fixed contact and the movable contact separate from and come in contact with each other.
Thereby, the movable plate 22 constitutes a temperature switch that electrically opens and closes a circuit between one external terminal connected to the above fixed contact and the other external terminal connected to the above fixation part.
The above movable plate 22, as shown in
The substrate 21 comprises cut-out portions 24 at both sides. Each cut-out portion 24 is formed to have a width “c” that is greater than the width “d” of the pawl part 23 of the movable plate 22, and has a depth “e” that is greater than the tip length “f” of the pawl part 23.
The relationships among the above side portion's thickness “a” of the substrate 21, the opening height “b” of the pawl part 23 of the movable plate 22, the width “c” of the cut-out portion 24 of the substrate 21, the width “d” of the pawl part 23 of the movable plate 22, the depth “e” of the cut-out portion 24 of the substrate 21, and the tip length “f” of the pawl part 23 of the movable plate 22 can be expressed as “a”<“b”, “c”>“d”, and “e”>“f”.
When the above movable plate 22 is attached to the substrate 21, first, the pawl part 23 is fitted into the cut-out portion 24 of the substrate 21 as indicated by the arrow “g” in
Thereby, both of the cut-out portions 24 (only one of the two is shown) of the substrate 21 are caught by the pawl part 23 (of the fixation part) of the movable plate 22, and the movable plate 22 is fixed to the substrate 21.
As shown in
As shown in
The relationships among the above thickness “i” of the side portion 24 of the substrate 21, the opening height “j” of the pawl part 28 of the movable plate 22, the width “k” of the second cut-out portion 27 of the substrate 21, the width “l” of the pawl part 28, of the movable plate 22, the depth “m” of the second cut-out portion 27 of the substrate 21, and the tip length “n” of the pawl part 28 of the movable plate 22 can be expressed as “i”<“j”, “k”>“l”, and “m”>“n”.
When the above movable plate 22 is attached to the substrate 21, first, the pawl part 28 of the movable plate 22 is fitted into the second cut-out portion 27 of the substrate 21 as indicated by the arrow “q” in
Thereby, a width-direction end 28-1 in the downstream sliding direction of the pawl part 28 is positioned by abutting a gap portion 24-1 between the first cut-out portion 26 and the side portion 24. Also, the pawl part 28 catches the side portion 24 including the first cut-out portion 26 of the substrate 21, and the movable plate 22 is fixed to the substrate 21.
As described above, according to the second embodiment of the present invention, because the substrate 21 includes the first cut-out portion 26 and the second cut-out portion 27, when the pawl part 28 of the movable plate 22 is inserted into the second cut-out portion 27 and the plate slides in the direction of the first cut-out portion 26, it is easy to position the plate by sliding the tip of the pawl part 28 to the end surface of the first cut-out portion.
As shown in
The movable plate 22 comprises an elastic locking part 29 that is adjacent to the pawl part 28 at the sliding-direction-upstream side as indicated by the arrow “q” and that has an L-shaped cross section having a sponson length that is smaller than that of the pawl part 28. Additionally, the dimensions of the above second cut-out portion 27 and the pawl part 28 are the same as those in the case of
As indicated by the arrow “r” in
Then, when the pawl part 28 slides in the direction of the first cut-out portion 26 as indicated by the arrow t in
Further, a width-direction-end portion 29-2 in the downstream sliding direction of the elastic locking part 29 abuts a gap portion 24-2 between the first cut-out portion 26 and the second cut-out portion 27, and the movable plate 22 is positioned on the substrate 22.
As described above, according to the third embodiment of the present invention, an L-shaped locking elastic part that is bent at a right angle in, for example, a downward direction is provided to a downstream portion in the sliding direction of the pawl part 28 of the movable plate 22. Accordingly, when the pawl part 28 is inserted into the second cut-out portion 27 and slides in the direction of the first cut-out portion 26, the elastic locking part 29 drops to overlap the second cut-out portion 27 before the tip of the pawl part 28 abuts the end surface of the first cut-out portion.
As described above, because the elastic locking part 29 drops to overlap the second cut-out portion 27, once the pawl part 28 slides in the direction of the first cut-out portion 26, the pawl part 28 catches the end part 24 at the first cut-out portion 26, and is prevented from sliding back.
In other words, the movable plate 22 that is once fixed to the substrate 21 gets in a fixed state with respect to the substrate 21.
Also, it is possible to configure the engagement portion in the present embodiment in such a manner that the outer-end surface having the width “l” of the pawl part 28 of the movable plate 22 does not extend beyond the end surface of the side portion 24 of the substrate 21.
By employing the above configuration, it is possible to avoid the trouble that occurs when the substrate 21 including the movable plate 22 (i.e., the substrate 21 including a temperature switch) is provided to an external device, whereupon an insulation material cannot be set to a space between the side-end surface of the substrate 21 and the external device due to the projection of the pawl part 28 of the movable plate 22.
The substrate 21 according to the fourth embodiment shown in
Also, the opening height “x” of the pawl part 30 of the movable plate 22 according to the present embodiment shown in
Additionally, the relationship between the dimensions of the pawl part 30 of the movable plate 22, except for the opening height “x”, and the dimensions of the second cut-out portions 27 is the same as the relationship between the pawl part 28 of the movable plate 22 and the second cut-out portion 27 of the substrate 21 shown in
In other words, in
Additionally, in the above example, the simple configuration of the pawl part 30 shown in
The configuration of the pawl part 30 shown in
In the configuration of the engagement portion according to the fourth embodiment, it is possible to not only prevent the outer-end surface having the width “l” of the pawl part 30 of the movable plate 22 from extending beyond the end surface of the side portion 24 of the substrate 21, but also from extending beyond the bottom surface of the substrate 21.
By employing the above configuration, it is possible to avoid the trouble that occurs when the substrate 21 comprising a temperature switch together the movable plate 22, is provided to an external device, whereupon an insulation material cannot be set to a space between the side-end surface of the substrate 21 and the external device or between the bottom surface of the substrate 21 and the external device due to the projection of the pawl part 28 of the movable plate 22.
However, the main body of the substrate 21 according to the present embodiment comprises two substrates, i.e., an upper substrate 31 and a lower substrate 32, and the first cut-out portion 26 is formed on the upper substrate 31, which is a different point from that in the configuration shown in
The substrate 21 according to the present embodiment is the same as that shown in
In this case, similar to the fourth embodiment, it is possible to prevent the outer-end surface having the width “l” of the pawl part 30 of the movable plate 22 not only from extending beyond the end surface of the side portion 24 of the substrate 21, but also from extending beyond the bottom surface of the substrate 21.
By employing the above configuration, it is possible to avoid the trouble that occurs when the substrate 21 comprising a temperature switch together the movable plate 22, is provided to an external device, whereupon the thermal contact and thermal insulation is disturbed when, for example, the substrate 21 is made of two ceramic substrates including a heater, because there is not a projection of the pawl part 28 of the movable plate 22 on the side-end surface of the bottom surface of the substrate 21.
Also,
In
Also, one end of the substrate 21 in the longitudinal direction (the lower half of the rectangle is omitted in
The external terminal 35a is covered to its base by an insulation member 36a except for a connection part 35a-1 that is connected to one terminal of one external device. The external terminal 35b is covered to its base by an insulation member 36b except for a connection part 35b-1 connected to the other terminal of the external device and except for a base-vicinity-portion 35b-2.
The movable plate 22 comprises a movable part 37 and a fixation part 38 in an integrated manner by performing stamping, embossing, and bending on an elastic plate member. The movable part 37 comprises a movable contact 39 disposed at a position that faces the above fixed terminal 34. The fixation part 38 comprises a connection part 41 that is connected, in a pressure contacting manner, to the other external terminal of the above two external terminals on the substrate 21.
A terminal part 41 extends from one (the left) side portion of the fixation part 38 of the movable plate 22 parallelly to the movable part 37, has a gap portion 42 with two bent portions formed approximately at the middle of the extending portion, and is distorted by the elasticity of itself such that the end portion (a terminal part 41) is in a pressure contact with the external terminal 35b of the substrate 21.
Also, this movable plate 22 comprises a bimetal 43 that is in the shape of a shallow bowl as a thermally-actuated element that is disposed between the movable part 37 and the fixation part 38 and loosely attached to the movable plate 22.
The position of this bimetal 43 is loosely fixed to pawl parts 44 that are formed at two places, and formed by extending the terminal parts of the fixation part 38 of the movable plate 22 to both sides, and by bending these extended parts at a right angle and the root part of the movable part 37 that continues from the fixation part 38 by using two L-shaped concave parts 45 (they are convex to the direction of the bimetal 43) formed by the cutting and extruding.
Also, the movable part 37 has a tongue piece 46 that is made by cutting and that extends from the base of the movable plate 37 to the position corresponding to the center of the bimetal 43. Also, an oval concave part 47 (convex to the direction of the bimetal 43) is formed at the position adjacent to and above the movable contact 39 by extruding it from the surface (the side toward the reader in the figure).
In the above configuration, the tongue piece 46 of temperature switch 33 according to the present embodiment is in a position of pressure contact with the center part of the bimetal 43 that is convex to the side toward the reader in
Thereby, the heat is surely conducted to the bimetal 43, and the bimetal 43 can efficiently detect the heat on the surface of the substrate 31. Accordingly, the heat capacity of the bimetal increases. Also, in this state, the circuit between the fixed contact 34 and the movable contact 39 is closed as shown in
This bimetal 43 has the temperature characteristic of inverting the warping direction at a prescribed temperature as shown in
As described above, the movable plate 22 constitutes a temperature switch that electrically opens and closes the circuit between one external terminal 35a that is connected to the fixed contact 34 and the other external terminal 35b that is connected to the terminal part 41 of the fixation part 38.
As explained above, in the temperature switch 33 according to the present invention, by attaching the movable contact 39 to the movable plate 22 (movable part 37) and by forming a terminal part at a part (fixation part 38) of the movable contact 39, the terminal part 41 of the movable plate 22 is connected to the outer terminal 35b (35b-2) and the movable plate 22 is fixed to the ceramic substrate 21 only by inserting and sliding the pawl part 30 into and on the side-cut-and-engagement portion of the substrate 21.
As a result of this, only a step of fitting is required, thus devices such as a special jig or the like are not required, and accordingly the easy assemblies are realized such that the number of steps required in the assembly is greatly reduced.
Also, by providing an elastic locking part that limits the direction in which the pawl part slides after being inserted into the substrate-side-cut-engagement portion, it is possible to attain an excellent stability after attaching.
Also, the engagement portion of the movable plate is not greater than the outer dimension of the ceramic substrate, and accordingly it is easy to handle the movable plate in view of insulation.
As described above, the temperature switch according to the present invention can easily be assembled without devices such as a special jig or the like, and the present invention can be applied to all the industries in which temperature switches that can perform temperature adjustment of ceramic substrates are used.
Number | Date | Country | Kind |
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2005-299651 | Oct 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2006/315578 | 8/7/2006 | WO | 00 | 2/22/2008 |