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EP 0 095 315 B1 |
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EUROPEAN PATENT SPECIFICATION |
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Mention of the grant of the patent: |
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25.03.1987 Bulletin 1987/13 |
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Date of filing: 18.05.1983 |
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International Patent Classification (IPC)4: H01H 37/76 |
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Heat sensitive circuit interrupter
Wärmeempfindlicher Leitungsunterbrecher
Interrupteur de circuit sensible à la chaleur
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Designated Contracting States: |
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DE FR GB IT NL SE |
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Priority: |
22.05.1982 GB 8214998
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Date of publication of application: |
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30.11.1983 Bulletin 1983/48 |
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Applicant: HEAT TRACE LIMITED |
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Hazel Grove
Stockport, Cheshire SK7 5DA (GB) |
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Inventors: |
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- Malone, Neil Shaw
c/o Heat Trace Limited
Hazel Grove
Stockport, SK7 5DA (GB)
- Boshell, Paul Michael
Heaton Chapel
Stockport (GB)
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Representative: Allman, Peter John et al |
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MARKS & CLERK,
Sussex House,
83-85 Mosley Street Manchester M2 3LG Manchester M2 3LG (GB) |
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Note: Within nine months from the publication of the mention of the grant of the European
patent, any person may give notice to the European Patent Office of opposition to
the European patent
granted. Notice of opposition shall be filed in a written reasoned statement. It shall
not be deemed to
have been filed until the opposition fee has been paid. (Art. 99(1) European Patent
Convention).
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[0001] The present invention relates to a heat sensitive circuit interrupter.
[0002] There are many applications in which a reliable heat sensitive circuit interrupter
can be used to advantage. For example an interrupter which operates to interrupt a
circuit when exposed to a temperature at or above a predetermined critical temperature
can be used to trigger an alarm or any other appropriate response. One possible use
of an interrupter is to monitor the temperature of an item of equipment and to shut
down that equipment when the critical temperature is detected.
[0003] Thermostats of conventional type can perform the function of a circuit interrupter.
Thermostats do suffer however from the limitation that they can sense the temperature
in their immediate vicinity but cannot detect overheating outside that vicinity. Thus
in many circumstances thermostats can only be used if the expense of installing a
larger number of them can be justified. For example, it is highly desirable to be
able to detect overheating of cables whether these cables are themselves used for
heating purposes or are simply used to carry power or information signals. Thermostats
cannot be used to detect localised overheating in cables at acceptable cost.
[0004] Heating cables which are used for example to protect process plant against frost
are generally referred to as heating tapes. Such tapes are wrapped around pipework
and covered in insulation. It is not possible to detect "hot spots" reliably in the
tape by monitoring current supplied or the tape resistance and thus the tapes and
the systems in which they are incorporated must be designed to be "fail safe" if they
are to be used in hazardous areas. A fail safe design is one in which any predictable
fault cannot result in overheating. A failsafe design is expensive because it requires
a higher degree of complexity and a higher nominal capacity than would be the case
if the design was not required to accommodate a variety of possible fault conditions.
[0005] It has been known for may years that the heating of an electrical circuit above a
critical temperature can be detected by incorporating in the circuit a circuit interrupter
in the form of a wire which melts at the critical temperature. For example British
Patent No. 336,270 dated 1929 proposes a heating element energised via a wire which
melts to break the supply circuit when the heating element becomes overheated. Such
arrangements have not found acceptance however because it is generally necessary to
cover the wire in insulation and when the wire melts its insulation often retains
the molten metal in its initial position at least for some time, maintaining electrical
continuity.
[0006] This molten metal retention effect is described in British Patent No. 1 164 238 which
proposes to overcome the problem by supporting the meltable wire without insulation
inside a stiff insulating tube defining sufficient space internally to allow the molten
metal to flow easily away from its initial position. One way of providing this space
is to fill the interior of the stiff tube with an insulating substance that is non-flammable
and disintegrates or melts at a temperature lower than that at which the meltable
wire melts. Examples of such fillers given are silicon grease or a paste flux.
[0007] British Patent No. 1 141 234 also refers to molten metal retention, and suggests
overcoming the problem by providing a body which is capable of absorbing the molten
metal.
[0008] Both the above suggested solutions to the problem of molten metal retention are undesirable
as they require non-standard extra features which cannot be included in cables at
low cost.
[0009] More recently, proposals have been made as described in published PCT Application
WO 83/ 01138 to provide a monitoring cable in which a meltable conductor is separated
from another conductor by a permeable insulator. When overheating occurs molten conductor
diffuses through the insulator and the resultant drop in resistance between the two
conductors is detected by suitable monitoring equipment. Accordingly this device relies
upon the fact that the molten portion of the meltable conductor remains in electrical
contact with the unmelted portion of the meltable conductor leading to the monitoring
equipment.
[0010] Flux is used in conventional meltable alloys such as solder to help the molten metal
"wet" a surface to which it is to adhere. Accordingly it could reasonably be assumed
that introducing flux into a sheathed meltable wire would increase the probability
of any molten portion of the wire maintaining electrical continuity. Surprisingly
it has been discovered however that this is not the case.
[0011] It is an object of the present invention to provide an improved circuit interrupter.
[0012] According to the present invention, there is provided a heat sensitive circuit interrupter
comprising an electrical conductor made from a material of predetermined melting temperature
and an electrically insulating member supporting the conductor the electrically insulating
member being able to withstand temperatures higher than the melting temperature of
the electrical conductor characterised in that the heat sensitive circuit interrupter
is in the form of a flexible elongate cable along the length of which the electrical
conductor extends, the electrical conductor is made from a solder which incorporates
flux, and the electrically insulating member is a sheath which encases the electrical
conductor, the material of the electrical conductor and the material of the electrically
insulating member being such that when the electrical conductor is melted at any locale
along the length of the cable the contact angle between the molten conductor and the
electrically insulating member is sufficiently large for the molten conductor to flow
into separated drops and thereby break the electrical continuity of the electrical
conductor and provide an indication of overheating at said locale.
[0013] Solders consisting of 60% tin, 40% lead and incorporating longitudinal cores of flux
have proved particularly successful, such solders being used conventionally for making
electrical connections. The solder may be rolled to form a flat strip.
[0014] The present invention is based on the known theory of the behaviour of a liquid when
placed on a solid flat surface, which behaviour is dependent upon the contact angle.
The contact angle is defined as the angle subtended by the flat surface and a tangent
to the liquid surface drawn from the edge of the liquid in a plane perpendicular to
the flat surface and the edge of the liquid. If this contact angle is small, the liquid
will "wet" the flat surface. If the contact angle is large, the liquid will form drops
or bubbles.
[0015] The contact angle is the resultant of three thermodynamic forces F,, F
2 and F
3 that act on each interface in the liquid/solid/surrounding vapour system. These forces
are related as follows:
F, = F2 + F3 cos C
where C = contact angle
F, = surface free energy of the solid/vapour interface
F2 = surface free energy of the solid/vapour interface
F3 = surface free energy of the liquid/vapour interface (surface tension)
[0016] The presence of a flux in a molten solder modifies these thermodynamic forces and
hence will affect the contact angle. It has been discovered that a melted solder without
flux will lie as a liquid film and not contract into separated drops, whereas melted
solder with flux will contact into bubbles.
[0017] In conventional solder, the flux is used to help the liquid to wet the surface. In
contrast, in the present invention, flux is used to cause the liquid solder to separate
into separated drops or bubbles. This contrast can be explained by considering the
3 possible effects that the flux has.
[0018]
1) It chemically removes (or corrodes) any oxides or imperfections in the flat surface
that tend to give the surface a high surface energy.
2) It chemically removes (or corrodes) any oxides of lead and tin that may have formed
on the solder surface.
3) Excess flux provides a thin low energy film upon which the liquid solder can move
more easily.
[0019] In conventional soldering the removal of deposits on the solid surface is the dominant
effect and hence the solder will wet the surface, whilst in the present invention
the removal of oxide film in the solder is the dominant effect and hence the surface
tension of the liquid solder will cause it to flow into low energy forms, that is
drops or bubbles.
[0020] An embodiment of the present ivention will now be described, by way of example, with
reference to the accompanying drawing which is an end view of a heating tape incorporating
a heat sensitive circuit interrupter according to the invention.
[0021] The illustrated heating tape comprises a sheath 1 within which two copper foils 2,
3 are encased. A woven heating element 4 is positioned beneath the foils but electrically
insulated from them by a web 5 of insulating material. A pair of foils 6, 7 of solder
are positioned on a support film 8 above the copper foils 2, 3 so as to be separated
from the copper foils by a web 9 of insulating material. The support film 8 may be
of glass fibre or the plastics marked at "Kapton" 11. Connections are made between
the copper foils 2, 3 and the heating element 4 by inserting rivets through the heating
elements and the copper foils at spaced locations along the length of the tape. For
example rivets could be placed at one metre intervals along each foil, the rivets
on one foil being staggered by 50 cm relative to the rivets on the other foil. A heating
tape having a woven heating element and foil conductor structure of this type is described
in British Patent No. 1 523 129.
[0022] The illustrated heating tape is made up by forming a core comprising the foil conductors
2, 3 embedded in an insulating body including webs 5 and 9. The outline of the core
is indicated by a dashed line 10 in the drawing. The solder foils 6,7 7 are then adhered
to the film 8. The heating element 4 is pressed against one side of the core, and
secured by rivets to the foils 2, 3, and the film 8 is pressed against the other side.
The resulting assembly is then encased in the sheath 1 by an extrusion process.
[0023] The tape may have any convenient dimensions, e.g. 20 mm wide and 4 mm thick. The
solder foils 6, 7 may be formed by rolling out conventional fine multi-core lead/tin
solder wire as used for making connections to electronic components to form a strip
approximately 4 mm wide. It has been found that using such a solder foil a break of
some 10 mm width occurs in the foil as soon as it is heated to its melting point,
the molten solder flowing away from the break to thicken the ends of the foil on either
side of the break.
[0024] Solders can be easily prepared which melt at well defined temperatures over a wide
range of temperatures, e.g. 100°C to 300°C. Thus the illustrated tape can be used
for a wide variety of purposes.
[0025] It is possible to dispense with the copper foils 2, 3 and use the solder foils 6,
7 to supply energy to the heating element. In some circumstances this might not be
so advantageous however as if power is supplied via the solder, sparks might occur
when it melts and breaks. In contrast in the illustrated arrangement a low voltage
monitoring circuit could be connected between the foils 6, 7 at one end of the tape,
the other ends of the foils 6, 7 being connected together. With a low voltage monitoring
circuit there is no risk of sparking.
[0026] It will be appreciated that one of the solder foils 6, 7 could be replaced by a nonfusible
conductor of for example copper.
[0027] It will be appreciated that the invention has applications not related to heating
tapes. For example a monitoring tape could be produced having only one or two solder
conductors within it and no heating element or separate supply conductors. The monitoring
tape could then be placed in areas where it is desired to detect excessive temperatures,
e.g. in electrical cable circuit, or in the ceiling of a warehouse, and connected
to a simple circuit adapted to sound an alarm if the solder conductor breaks. The
monitoring tape could also be incorporated in equipment, e.g. the windings of electric
motors, to automatically shut the equipment down in the event of overheating.
[0028] The illustrated embodiment shows the solder conductors in the form of thin foils.
It will however be appreciated that the solder may be in other forms to suit particular
applications providing that once molten it is capable of flowing to form a break.
[0029] Experiments have shown that both single and multi-core fluxed solder work satisfactorily
although multi-core solder is particularly good as it flows more freely to form separate
balls of molten. metal. Simple unfluxed solder generally does not work as it melts
but does not flow easily to form a break. Unfluxed solder lying in flux powder will
also not work effectively if the flux powder is allowed to oxidise.
[0030] The described embodiment of the invention utilizes a solder in which flux is provided
in the form of cores. The solder could however be externally coated with flux.
[0031] The term "solder" is used herein to mean any electrically conductive fusible material.
Generally solder will be in the form of a low melting point fusible alloy. The flux
can be of any suitable type, but care must be taken to ensure that the flux is stable
at the normal temperatures to which it is in use exposed.
1. A heat sensitive circuit interrupter comprising an electrical conductor made from
a material of predetermined melting temperature and an electrically insulating member
supporting the conductor the electrically insulating member being able to withstand
temperatures higherthan the melting temperature of the electrical conductor characterised
in that the heat sensitive circuit interrupter is in the form of a flexible elongate
cable along the length of which the electrical conductor (6, 7) extends, the electrical
conductor is made from a solder which incorporates flux, and the electrically insulating
member is a sheath (1) which encases the electrical conductor, the material of the
electrical conductor and the material of the electrically insulating member being
such that when the electrical conductor (6, 7) is melted at any locale along the length
of the cable the contact angle between the molten conductor and the electrically insulating
member (1) is sufficiently large for the molten conductor to flow into separated drops
and thereby break the electrical continuity of the electrical conductor and provide
an indication of overheating at said locale.
2. A heat sensitive circuit interrupter according to claim 1, wherein the conductor
(6, 7) is in the form of a flattened strip.
3. A heat sensitive circuit interrupter according to claim 2, wherein the conductor
(6, 7) is formed by rolling flat a cylindrical solder wire incorporating a plurality
of cores of flux.
4. A heat sensitive circuit interrupter according to any preceding claim, comprising
two conductors (6, 7) arranged in parallel at least one of which is the said conudctor
made from a material of predetermined melting temperature, the conductors being connected
together at one end such that their electrical continuity can be monitored from the
other end.
5. A heat sensitive circuit interrupter according to any preceding claim, incorporated
in an electrical heating tape.
6. A heat sensitive circuit interrupter according to claim 5, wherein the said conductor
(6, 7) made from a material of predetermined melting temperature constitutes a heating
element of the heating tape.
7. A heat sensitive circuit interrupter according to any preceding claim, wherein
the support member is in the from of a sheath (1, 5, 9) which encases the or each
electrical conductor (6, 7).
1. Wärmeempfindlicher Schaltungsunterbrecher, mit einem elektrischen Leiter aus einem
Material vorgegebener Schmelztemperatur, und mit einem elektrisch isolierenden Element,
welches den Leiter trägt, wobei das elektrisch isolierende Element in der Lage ist,
höhere Temperaturen als die Schmelztemperatur des elektrischen Leiters auszuhalten,
dadurch gekennzeichnet, daß der wärmeempfindliche Schaltungsunterbrecher in Form eines
flexiblen länglichen Kabels ausgebildet ist, über dessen Länge sich der elektrische
Leiter (6, 7) erstreckt, daß der elektrische Leiter aus einem Lot besteht, welches
Flußmittel enthält, und daß das elektrisch isolierende Element ein Mantel (1) ist,
der den elektrischen Leiter umgibt, wobei das Material des elektrischen Leiters und
das Material des elektrisch isolierenden Elementes so gewählt sind, daß dann, wenn
der elektrische Leiter (6, 7) an irgendeinem Ort über die Länge des Kabels geschmolzen
wird, der Kontaktwinkel zwischen dem geschmolzenen Leiter und dem elektrisch isolierenden
Element (1) für den geschmolzenen Leiter ausreichend groß ist, so daß er in separate
Tropfen fließt und dadurch den elektrischen Durchgang des elektrischen Leiters unterbricht
und eine Anzeige der Überhitzung an diesem Ort liefert.
2. Wärmeempfindlicher Schaltungsunterbrecher nach Anspruch 1, wobei der Leiter (6,
7) in Form eines flachen Streifens ausgebildet ist.
3. Wärmeempfindlicher Schaltungsunterbrecher nach Anspruch 2, wobei der Leiter (6,
7) durch Flachwalzen eines zylindrischen Lotdrahtes, der einer Vielzahl von Kernen
aus Flußmittel enthält, gebildet ist.
4. Wärmeempfindlicher Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche,
enthaltend zwei parallel apgeordnete Leiter (6, 7), von denen mindestens einer der
Leiter aus einem Material vorgegebener Schmelztemperatur ist, wobei die Leiter an
einem Ende miteinander verbunden sind, so daß ihr elektrischer Durchgang von dem anderen
Ende überwacht werden kann.
5. Wärmeempfindlicher Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche,
eingebaut in ein elektrisches Heizband.
6. Wärmeempfindlicher Schaltungsunterbrecher nach Anspruch 5, wobei der Leiter (6,
7) aus einem Material vorgegebener Schmelztemperatur ein Heizelement des Heizbandes
bildet.
7. Wärmeempfindlicher Schaltungsunterbrecher nach einem der vorhergehenden Ansprüche,
wobei das Trägerelement in Form eines Mantels (1, 5, 9) ausgebildet ist, der den oder
jeden elektrischen Leiter (6, 7) umschließt.
1. Interrupteur de circuit thermosensible comprenant un conducteur électrique constitué
par un matériau ayant une température de fusion prédéterminée et un élément isolant
électrique portant le conducteur, l'élément isolant électrique étant capable de supporter
des températures plus élevées que la température de fusion du conducteur électrique,
interrupteur caractérisé en ce que l'interrupteur de circuit thermosensible présente
la forme d'un cable allongé flexible, le long duquel s'étend le conducteur électrique
(6, 7), que le conducteur électrique est constitué par de l'étain comprenant un fondant
et que l'élément isolant électrique est une gaîne (1) qui enveloppe le conducteur
électrique, le matériau du conducteur électrique et le matériau de l'élément isolant
électrique étant tels que, lorsque le conducteur électrique (6, 7) est fondu en n'importe
quelle position le long du cable, l'angle de contact entre le conducteur fondu et
l'élément isolant électrique (1) soit suffisamment élevé pour que le conducteur fondu
s'écoule par des gouttes séparées et coupe ainsi la continuité électrique du conducteur
électrique et fournisse une indication de surchauffe en ce point.
2. Interrupteur de circuit thermosensible selon la revendication 1, caractérisé en
ce que le conducteur (6, 7) à la forme d'une bade aplatie.
3. Interrupteur de circuit thermosensible selon la revendication 1, caractérisé en
ce que le conducteur (6, 7) est formé par enroulement à plat d'un fil d'étain cylindrique
comprenant une pluralité d'âmes de fondant.
4. Interrupteur de circuit thermosensible selon l'une quelconque des revendications
précédentes, comprenant deux conducteurs (6, 7) disposés parallèlement, dont au moins
un est le conducteur constitué par un matériau à température de fusion prédéterminée,
les conducteurs étant reliés entre eux à une extrémité de façon que leur continuité
électrique puisse être commandée par l'autre extrémité.
5. Interrupteur de circuit thermosensible selon l'une quelconque des revendications
précédentes, incorporé dans une bande chauffante électrique.
6. Interrupteur de circuit thermosensible selon la revendication 5, caractérisé en
ce que le conducteur (6, 7) constitué par un matériau à température de fusion prédéterminée,
forme un élément chauffant de la bande chauffante.
7. Interrupteur de circuit thermosensible selon l'une quelconque des revendications
précédentes, caractérisé en ce que l'élément de support a la forme d'une gaîne (1,
5, 9) qui enveloppe le ou chaque conducteur électrique (6, 7).