NL8400329A - Overheating protection circuit for electric blanket - has logic circuit cutting off power in response to small currents in detector wire - Google Patents

Abstract

The output of a flip-flop, consisting of two NAND gates (P1,P2) cross-coupled by two resistors (R3,R4), is fed to a buffer consisting of two parallel NAND gates (P3,P4). The buffer output (13) is fed to a current supply cut-off circuit, e.g. a crowbar thyristor which blows a replaceable fuse. When the blanket is plugged into the mains supply, a reference voltage (Uref1) is applied to the flip-flop, setting it in the normal, i.e. safe, state. The hot-spot detector wire is connected via a diode (D1) and resistor (R2) to the flip-flop input. If the detector wire current exceeds 1 mA, the flip-flop changes state and operates the cut-off circuit. The flip-flop can be reset by operating a reset switch (S) which shorts out a dropper resistor (R1) between the setting reference (Uref1) and a second reference (Uref2).

Description

! * - .- i "· 5 · * -1- 22969 / JF / ts

Brief designation Electrically heated devices with a heating cable provided with an overheating protection circuit.

The invention relates to a heating device comprising a heating cable and a heating cable connected to the heating wire by means of a fusible link connected to the heating wire by means of a heating cable separated by insulating material with an inversely proportional temperature dependence for the electrical resistance for the electrical resistance. heating wire is supplied with current and a protective member connected to the scanning wire for interrupting the power supply to the heating wire in the event of overheating, in which at least part of the current supplied to the heating wire occurs on the scanning wire.

An apparatus of the above-mentioned type is known from British patent application 2,028,607.

In this known device, the protection member is an elegant / thermal protection member, in particular a resistor electrically connected to the scanning wire and thermally coupled to the fusible link.

In order to destroy the melting protection member in the event of overheating, the resistance must generate the necessary amount of heat, for which a proportionately large current is required. This means that the scan wire must then conduct this large current, which can only be the case when the resistance of the insulation is very low, or a short circuit occurs between the heating wire and the scan wire due to the high temperature. melting the insulation material.

In the case of very localized overheating, this device will have to short-circuit between the heating wire and the sensing wire for the sensing wire to conduct enough current to heat up the resistor to destroy the fuse, since if the insulation does not melt due to the integrating effect of the scanning wire, the current flowing through it is too small.

35 Ret above implies that in case of very local overheating the power supply will only be interrupted O \ when the heating cable is irreparably damaged.

Due to the fact that the heating cable is often included in, for example, an electrically heated bed cover, irreparable damage to the heating cable also renders the bed cover unusable and will have to be used. be replaced, which entails the necessary costs.

Technically, the necessary thermal coupling of the resistor to the fusible link is a limiting factor in the design of the heaters in question.

The object of the invention is to eliminate the above-mentioned drawbacks and to this end provides a device of the type mentioned in the preamble, characterized in that the protection member is an electrical protection member which reacts in response to a current fed to the heating wire low current occurring on the scanning wire generates an alarm signal which causes the interruption of the power supply to the heating wire.

The advantage of the invention is that the protection takes place purely electronically, so that it can respond more quickly to faults, which in turn does not lead to destruction of the heating circuit by every fault and not only to avoid a fire hazard.

The heating device, for instance comprising the electrically heated bed cover, can, after replacing the fusible safety device or in the case of a power supply control device, reactivate this power supply control device, for example, by means of a switch, if the cause of the the fault has been rectified.

The invention will now be described in more detail with reference to two simple embodiments of the invention and with reference to the drawing, in which: Fig. 1 is a circuit diagram of the first embodiment of the invention; and FIG. 2 is a circuit diagram of a second embodiment of the invention.

30. The heating cable used in the heating device, in particular comprising an electrically heated blanket, pillow or the like, can be a coaxial heating cable. The core wire or scanning wire is then wound on a core, which gives the heating cable a firm grip, while a sleeve of insulating material is provided thereon, on which respectively the scanning wire is arranged off the heating wire, which is completely enclosed by a heel of insulating material. It isola-

Option material between the heating wire and sensing wire has an inversely proportional temperature dependence of the electrical resistance. Due to the V 8400329 -τ '% _3_ 22969 / JF / ts ♦ in particular locally, the heating wire J becoming unacceptably warmer as a result of, for example, improper use of the blanket, the heat-insulating material between the heating wire and the scanning wire becomes warmer and therefore the electrical resistance of the insulating material 5 decreases. At a certain temperature of the insulating material, therefore, an electronically detectable crosstalk signal will occur on the scanning wire, which crosstalk signal is at least part of the current supplied to the heating wire. The invention is not otherwise limited to this special type of heating cable. Likewise, a separate heating cable and separate sensing cable could be used as long as the two cables are thermally coupled. The scanning cable can consist of two scanning wires, which are separated from each other by the above-mentioned insulating material. However, the coaxial cable is preferred. In addition, it is noted that such heating cables are known per se in the art. In view of this, the heating cable is not shown in the drawing.

Furthermore, it is known per se in the state of the art to include a power supply control member between a power supply or a connection to the mains and the heating wire through a fusible link.

A potentiometer of the power supply control member can then be set manually in a specific position, after natural switching on, after which the desired temperature is set, for example, by a stepless setting, the power supply control member being at least dependent on the position of the potentiometer in successive intervals of a given duration always send a respective number, less than or equal to a maximum number of alternating half-periods of an alternating current to the heating wire. The number of half periods determines the temperature to be reached by the heating wire.

At the same time, the sense wire may also be a control wire when it is not made of a good conductor, such as copper, but of a material having a positive temperature dependence for the electrical resistance, such as nickel, where the resistance of the sense wire is a measure for the temperature of the heating cable and indirectly the electrically heated bed cover in which it is used. The sense / control wire can then be included in a feedback loop of the power supply control-35.org, allowing the power supply to be controlled to maintain the set desired value. The scan / control wire then also bids

This protects against overheating, because overheating will increase the temperature of the sensing / control wire, causing the current to flow. \ 8 4 0 0 3 2 9 ----------- ·> - '·

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-4- 22969 / JF / ts feed is reduced, it should be noted that with very local overheating change of resistance over a very small portion of the scan / control wire due to integrating action of this wire may not provide optimum protection. ____________ ... ------ - 5. It is also possible to use a good conductor for the scanning wire, but at a certain suitable location in the electrically heated bed cover, in which the heating cable is fitted, a resistor with a positive apply temperature coefficient and include it in the scan wire.

10. The currents occurring on the scanning wire in the case of very local overheating, for example by double folding the electrically heated blanket in which the heating cable is arranged, are in the order of magnitude of 1 mA. It will be clear that this current strength is insufficient for a resistor connected in series with the scanning wire to heat up sufficiently to cause it to inflate via thermal coupling with a fuse.

A first embodiment of a security member according to the present invention will now be described with reference to Fig. 1.

In FIG. 1, reference numerals 1 and 10 denote power supply terminal 20. points for connection to a power source or the mains, while reference numerals 3 and 4 indicate connection points to the power supply regulator (not shown in the drawing) or one end of the heating wire, respectively, and for connection to the other end of the heating wire indicated. A fuse 2 is fused between the connection points 1 and 3. Reference numeral 7 designates the connection point to the sensing wire, at which connection point, in the event of overheating, a current will occur which is supplied to an inverting amplifying member 8 by means of the resistor divider formed by resistors 5 and 6, the terminal of resistor 6 not connected to resistor 5 being connected. at a reference voltage U Between the node of the fuse 2 and the connection point 3, and a node between the connection points 4 e.n_J0 .is. an actuator for the fuse 2, in this case a triac 9, the ignition electrode of which is connected to the output terminal of the inverting amplifier 8, which may, for example, consist of four parallel-connected NAND gates.

The circuit of FIG. 1 operates as follows. In the case of particularly superheating, a weak signal occurs on the sensing wire ✓ and therefore on connection point 7. This signal is amplified and inverted by the inverting amplifier 8 and its output ignites the triac 9, thereby failing the fuse. Since the protection member according to figure 1 responds to a weak signal, no destruction of the heating cable occurs. In eliminating the cause of the overheating and installing a new fuse, in particular a fuse, the heating device, in particular the electrically heated blanket, can be used again. In other words, it simulates ignition Triac 'a complete short-circuit of the heating wire, 10. because it may be connected in parallel with the heating wire with the intervention of a current-supplying regulator. circuit according to Fig. 1, after a small current has occurred on the scanning wire, a total short-circuiting of the heating wire is simulated, so that the normally customary safety provision responds to this and the heating device is not destroyed.

Fig. 2 shows a second embodiment of the present invention.

20. In Fig. 2, reference numeral 17 denotes the connection point to the sensing wire and reference numeral 13 denotes connection point to a power supply control means (not shown in the drawing). Connection point 17 is connected to the cathode of diode D1, the anode of which is connected to resistor R2, which in turn is connected to its other terminal to the input of NON gate PI. The output of NAND gate P1 is connected by means of resistor R3 to the input of NAND gate P2, the output of which is in turn connected by means of resistor R4 to the input of NAND gate P1 . NAND gates F1 and P2 form a bi-stable member, especially a flip-flop. The input of NAND gate P1 and therefore the associated terminal of resistor R4 are connected to a reference voltage. The input of NAND gate P1 is further connected by means of a resistor R1 to a second reference voltage. Over resistor R1 a switch S may be provided, which will be discussed later. The parallel-connected 35. NAND gates P3 and P4, which are connected between the output of NAND gate P2 and junction 13, form a buffer.

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The circuit of FIG. 2 operates as follows.

NAND gate P1 has a preset via R1, which resets the flip-flop formed by NAND gate PI and P2. In case of overheating, vi§ occurs. diode D1 and resistor R2 have a weak signal at 5. NAND gate PT, which puts the flip-flop consisting of NAND gates P1 and P2, interrupting the power supply by the power supply controller to the heating wire or blocked. The flip-flop is held by RA. Because the flip-flop appeals to. a weak signal, in the order of magnitude of, for example, 1 mA, the heating wire and thus cable 10. is not damaged by the signaled overheating and once the measuring wire has cooled, the flip-flop can be reset by interrupting the voltage, for example, by pulling the plug out of the socket and then plugging it in again, or closing the switch S, if provided.

15. ' It will be clear that the invention is not limited to the two simple embodiments described above, but that the essence of the expression is that a weak signal occurring on the scanning wire is electronically detected and made suitable for electronic processing. blowing up a fuse or interrupting the power supply to the heating cable via a power supply control element in, for example, an electrically heated blanket.

Q 8400329

Claims (8)

1. Heater, comprising a heating wire and heating wire separated by insulating material with inversely proportional temperature dependence for the electric resistance and electric wire, a fusible link connected to the heating wire, through which current flows to the heating wire in operation is supplied and a protective member connected to the scanning wire for interrupting the power supply to the heating wire, in the event of overheating, at least a part of the current supplied to the heating wire on the scanning wire, interrupting the current supply to the heating wire, characterized in that electronic protection means is that in response to a current which is small on the scanning wire with respect to the current supplied to the heating wire, generates an alarm signal, which causes the interruption of the power supply to the heating wire. 2. Device according to claim 1, characterized in that the electronic protection member comprises an amplifier member for amplifying the signal received from the spacer wire and one between the output of the amplifier member and the junction between the fuse member and the heating wire. connected actuator for generating a destruction current for the fuse in the event of the signal on the sensing wire ._________________________ ..... _____ Device as claimed in claim 2, characterized in that the actuating member is an ac * connected in parallel to the heating wire, the ignition electrode of which is connected to the output of the amplifier member and the fuse protection member normally for short-circuit protection of the heating conductor is used fuse, where actuation of the triac simulates short circuit of the heating wire. _ ____ 4. Device as claimed in claim 1, characterized in that a power supply regulator is inserted in the connection between the fuse-safety member and the heating wire and the electronic protection member comprises a bi-stable member, which is placed on a scanning wire 35. signal which generates the alarm signal which causes the power supply controller to block or interrupt the power supply. Q 8400329 C® v V> -8- 22969 / JF / ts The device according to claim 4, characterized in that it further comprises a reset member for resetting the bi-stable member. 6. Device according to any one of claims 1-3, wherein a current supply control device is inserted in the connection between the melting safety device and the heating wire, or according to claim 4 or 5, characterized in that the scanning wire is made of a material having a positive temperature coefficient for the resistor or a resistance member having a positive temperature coefficient, which is thermally coupled to at least a portion of the heating wire and the sensing wire is connected to a feedback control input of the current supply control means. Device according to any one of the preceding claims, characterized in that the heating cable is arranged in a specific pattern in an electrically heated blanket, pillow or the like. Security member according to any one of claims 1-6. Eindhoven, June 1983 \ 8400329