WO2000034839A1

WO2000034839A1 - Electrical thermal appliance with remotely mounted temperature sensor

Info

Publication number: WO2000034839A1
Application number: PCT/EP1999/009185
Authority: WO
Inventors: Tang P. Har; Albertus P. J. Michels; Marinus Bliek
Original assignee: Koninklijke Philips Electronics N.V.
Priority date: 1998-12-08
Filing date: 1999-11-24
Publication date: 2000-06-15
Also published as: SG86341A1

Abstract

In an electrical thermal appliance, for example a pressing iron, the temperature of a hot surface (10) is sensed by a remotely mounted radiation sensor (12), for example a thermopile, through a waveguide (18) which guides thermal radiation from the hot surface (10) to the radiation sensor (12). Optionally, the radiation sensor (12) may directly observe an object heated by the hot surface (10), for example a cloth heated by the hot surface (10). The remote sensing of the temperature of the hot surface (10) provides an accurate temperature control without overshoot.

Description

Electπcal thermal appliance with remotely mounted temperature sensor

The invention relates to an electπcal thermal appliance compπsing: an electπcal heating element for heating an object, a temperature sensor for sensing a temperature of the object and means for controlling the electπcal heating element in response to the temperature of the object sensed by the temperature sensor. Such an electπcal thermal appliance, in particular a pressing iron, is known from United States Patent No. 5,042,179. Electronic thermostats in thermal appliances such as pressing irons and cooking devices are constituted of a temperature sensor, a power switch, a temperature setting device, usually a dial or push buttons, and a controller. The controller constantly compares the signals from the temperature sensor with the temperature set by the temperature setting device and determines whether or not energy is to be supplied to or cut off from the heating element of the appliance. For this purpose, the temperature sensor, usually a thermistor, i.e. a resistor with a positive (PTC) or a negative (NTC) temperature coefficient, is directly mounted on the surface to be heated by the electπcal heating element, i.e. on the soleplate of an pressing iron or on the hotplate of a cooking device. The thermistor is usually electπcally insulated from the surface to be heated by at least one insulation layer for safety reasons. This kind of temperature sensing provides a rather accurate temperature feedback to the controller, but there is always a delay in response time due to the heat transfer from a desired temperature sensing point of the surface to be heated to the actual mounting location of the temperature sensor. The delay in response time can also aπse from the mandatory insulation layers required in the mounting of the temperature sensor on the surface to be heated The delay reduces the performance of the temperature control as it causes overshoot and reduced switching range accuracy.

It is an object of the invention to provide an electπcal thermal appliance with an improved temperature control. For this purpose, according to the invention, the electπcal thermal appliance defined in the opening paragraph is characteπzed in that the temperature sensor is a radiation sensor mounted remotely from the object for sensing radiation emitted by the object.

The remotely mounted radiation sensor is directly exposed to the temperature of the desired temperature sensing point of the surface to be heated and provides a feedback signal nearly instantaneously. Hence there will be a minimal delay in response time, resulting in a more sensitive and more accurate temperature control without overshoot.

The non-contact temperature sensing concept according to the invention further has the advantage that insulation layers between the temperature sensor and the surface to be heated and the involved high voltage tests are not needed any more

The radiation sensor preferably compπses a waveguide having a first end mounted for receiving radiation from the object, and a thermopile mounted at a second end of the waveguide for convening the radiation into an electπcal signal. The waveguide may be a polyamide (Nylon) tube wnh a reflecting inner wall and provides electπcal insulation between the thermopile and the surface to be heated. The reflecting inner wall reflects the radiation and concentrates the radiation in the direction of the thermopile. The tube may be tapered to better concentrate the radiation in the direction of the thermopile. In order to prevent dust particles from enteπng the tube and polluting the reflecting wall, the open ends of the tube are covered by caps made of a mateπal which is transparent to the radiation to be sensed by the thermopile. Suitable mateπals for this purpose are heat resistive polyimide (Kapton) at the hot end of the tube nearby the surface to be heated, and polyethylene at the cold end of the tube where the thermopile is located.

The remotely mounted radiation sensor can be used in pressing irons in which the electπcal heating element heats a soleplate, the temperature of the soleplate of the pressing iron being remotely sensed by the radiation sensor. Other applications are cooking devices such as those in which the electπcal heating element heats a hotplate, the temperature of the hotplate being remotely sensed. The remotely mounted radiation sensor can also be used in thermal appliances such as pressing irons and cooking devices having a heat conductive surface heated by the electπcal heating element, for sensing the temperature of an object to be heated by the heat conductive surface For this purpose, the surface is provided with a window which enables the radiation sensor to look through the surface to the object. In the case of a pressing iron this object may be a cloth to be ironed and the radiation sensor directly measures the temperature of the cloth through the window in the soleplate. In the case of a cooking device this object may be the bottom of a cooking pan or the like, or a fluid in a deep-fat fryer or in an electπcal kettle, or a piece of food on the heated surface of an electπcal gπll.

These and other aspects of the invention will be descπbed and explained with reference to the appended drawings, in which:

Figure 1 is a circuit diagram of a conventional temperature control system for an electπcal thermal appliance. Figure 2 shows a pressing iron with a remotely mounted radiation sensor according to the invention;

Figure 3 shows a construction of a remotely mounted radiation sensor for use in a thermal appliance according to the invention; and Figure 4 shows a fuπher construction of a remotely mounted radiation sensor for use in a thermal appliance according to the invention.

In these Figures parts having the same function or purpose are denoted by the same references.

Figure 1 shows a circuit diagram of a conventional temperature control system for an electπcal thermal appliance, for example a pressing iron. An electπcal heating element 2 is connected in seπes with a switching device 4 between AC supply terminals 6 and 8. The heating element 2 heats a soleplate 10 in a known way, for example by means of a resistive heating element embedded in the soleplate 10. The temperature of the soleplate 10 is sensed by means of a temperature sensor 12 mounted at a suitable location on the soleplate 10. The temperature sensor 12 usually is a thermistor, i.e. a resistor with a positive temperature coefficient (PTC resistor) or with a negative temperature coefficient (NTC resistor), but other temperature sensitive devices such as semiconductor junctions can be used as well. For safety reasons the temperature sensor 12 is electπcally insulated from the soleplate 10 by means of one or more insulating layers. The temperature sensor 12 generates a sense signal representative of the temperature of the soleplate 10. A temperature setting device, for example a dial 14, generates a signal representative of a desired temperature. A controller 16 compares the sense signal from the temperature sensor 12 with the desired temperature and opens or closes the switching device 4 to maintain the soleplate 10 at the desired temperature. This contact type of temperature sensing provides a rather accurate temperature feedback to the controller 16, but there is always a delay in response time due to the heat transfer from a desired temperature sensing point of the soleplate 10 to the actual mounting location of the temperature sensor 12. The insulation layers between the temperature sensor 12 and the soleplate 10 also cause an additional delay The delay reduces the performance of the temperature control because it causes overshoot and reduced switching range accuracy Figure 2 shows a pressing iron with improved temperature control. The temperature sensor 12 is a radiation sensitive sensor mounted remotely from the soleplate 10, which sensor is exposed to the heated surface of the soleplate 10 through a waveguide 18. The electronic components of the controller 16 are placed on a pπnted circuit board 17 mounted inside the pressing iron. The radiation-sensitive sensor may be a commercially available thermopile sensor In this way the temperature sensor 12, directly "sees" the soleplate 10 from a distance and the aperture of the temperature sensor may be aimed at any suitable location on the heated surface of the soleplate 10 This has the advantage of a minimal thermal resistance between the location on the soleplate 10 to be sensed and the temperature sensor 12 No insulation layers are needed any more to meet safety requirements Another advantage is that no wmng is needed between the pπnted circuit board 17 of the controller 16 and a sensor on the hot soleplate 10. The thermopile sensor 12 may also form an integral part of the integrated circuit which performs the controller functions of the controller 16 The direct remote sensing of the temperature of the soleplate 10 provides a temperature feedback signal with a minimal delay and results in an accurate temperature control without overshoot.

Figure 3 shows in more detail the construction of the temperature sensor 12 in the pressing iron of Figure 2 The thermopile itself (not shown) is incorporated in a metal housing 20 which has a filteπng lens 22 to receive radiation and to focus the received radiation on the thermopile The thermopile sensor further has connection terminals 24 for connecting to the controller 16. The thermopile sensor is mounted at one end 26 of the waveguide 18, which is constructed as a polyamide (Nylon) tube The inner wall 28 of the polyamide (Nylon) tube is finished with a reflecting mateπal which reflects the radiation towards the thermopile sensor The tube may have a tapered shape to concentrate the radiation onto the thermopile sensor The other end 30 of the waveguide 18 is positioned nearby the mteπor surface of the soleplate 10, for example at a distance of 2 millimeters or less from the soleplate 10 In order to keep the reflecting inner wall of the polyamide (Nylon) tube clean, the open ends 26 and 30 of the waveguide 18 are covered by caps 32 and 34, respectively, made of a mateπal which is transparent to the radiation to be sensed by the thermopile Suitable mateπals for this purpose are heat resistive polyimide (Kapton) at the hot end 30 of the tube nearby the soleplate, and polyethylene at the cold end 26 of the tube where the thermopile is located. The thickness of the polyethylene cap 32 may be 1 millimeter or less and the cap 34 may be made from polyimide (Kapton) foil with a thickness of 40 micrometers or less The upper end 26 of the polyamide (Nylon) tube of the waveguide 18 and the thermopile sensor can be mounted in a plastic, e.g. polycarbonate, block 36 In the case of a steam iron this block 36 may rest on top of a water tank 38, but any other suitable position may be chosen The polyamide (Nylon) tube of the waveguide 18 is further positioned on a cover 40 which rests on top of the soleplate 10

Figures 2 and 3 also show an optional window 42 in the soleplate 10. By providing the window 42 in the soleplate 10 the temperature sensor 12 can directly "see" a cloth (not shown) to be ironed by the pressing iron and in this way the temperature of the cloth can be measured. The window 42 may be constituted by a hole in the soleplate 10 but can also be made of a by heat-resistive and radiation-transmitting mateπal, e.g. glass

Figure 4 shows a thermopile sensor 12 which monitors more than one location of the soleplate 10. For this purpose, the waveguide 18 has a multiple tube construction to collect radiation from several hot spots on the soleplate 10. In this way the hottest spot of the soleplate dictates the temperature control. Instead of simultaneously monitoπng several hot spots, it is further possible to observe different locations on the soleplate 12 on by one by means of the thermopile sensor 12. This can be realized, for example, by collecting the radiation from different locations on the soleplate 10 by means of glass fiber cables and by coupling the outputs of the glass fiber cables one by one to the thermopile sensor with optical switches.

The pπnciples of the invention are not limited to pressing irons, but can also be applied to other electπcal thermal appliances, such as cooking devices. In that case the electπcal heating element heats a hotplate or the like. The temperature of the hotplate is controlled in a fashion similar to that shown in relation to the soleplate of the pressing iron in Figures 2 and 3. By making a window the hotplate the temperature of the bottom of a cooking pan or the like, or the temperature of a fluid in a deep-fat fryer or in an electπcal kettle, or the temperature of a piece of food on the heated surface of an electπcal gπll can be sensed

Claims

CLAIMS:

1. An electπcal thermal appliance compπsing: an electπcal heating element (2) for heating an object (10), a temperature sensor (12) for sensing a temperature of the object and means (16) for controlling the electπcal heating element (2) in response to the temperature of the object (10) sensed by the temperature sensor (12), characteπzed in that the temperature sensor (12) is a radiation sensor mounted remotely from the object (10) for sensing radiation emitted by the object (10).

2. An electπcal thermal appliance as claimed in claim 1, wherein the object is a heat conductive surface (10) heated by the electπcal heating element (2).

3. An electπcal thermal appliance as claimed in claim 1, wherein the electπcal thermal appliance compπses a heat-conductive surface (10) for heating the object, the heat- conductive surface (10) being heated by the electπcal heating element (2), and the heat- conductive surface (10) having a window (42) for transmitting the radiation from the object to the radiation sensor (12).

4. An electπcal thermal appliance as claimed in claim 2 or 3, wherein the appliance is a pressing iron and the heat-conductive surface is a soleplate (10) of the pressing iron.

5. An electπcal thermal appliance as claimed in claim 2 or 3, wherein the appliance is a cooking device and the heat-conductive surface is a hotplate.

6 An electπcal thermal appliance as claimed m claim 1, 2, 3, 4 or 5, wherein the radiation sensor compπses a waveguide (18) having a first end (30) mounted for receiving radiation from the object (10), and a thermopile mounted at a second end (26) of the waveguide (18) for converting the radiation into an electπcal signal.

7. An electπcal thermal appliance as claimed in claim 6, wherein the waveguide (18) is a polyamide (Nylon) tube with a reflecting inner wall (28).

8. An electπcal thermal appliance as claimed in claim 6, further compπsing a polyimide (Kapton) foil (34) for coveπng the first end (30) of the waveguide (18).

9. An electπcal thermal appliance as claimed in claim 6, further compπsing a polyethylene cap (32) for coveπng the second end (26) of the waveguide (18).

10 An electπcal thermal appliance as claimed in claim 7, wherein the polyamide

(Nylon) tube is tapered for concentrating the radiation in the direction of the thermopile.

11. An electπcal thermal appliance as claimed in claim 1, wherein the temperature sensor (12) is mounted on a pπnted circuit board (17) which cames electronic components of the means (16) for controlling

12. An electπcal thermal appliance as claimed in claim 1, wherein the temperature sensor (12) is an integral part of an integrated circuit which performs control functions of the appliance.

13 An electπcal thermal appliance as claimed in claim 6, wherein the waveguide

(18) compπses a multiple guiding construction for simultaneously guiding radiation from different locations of the object (10)

14. An electπcal thermal appliance as claimed in claim 6, wherein the waveguide

(18) compπses glass fiber cables and optical switches for selectively coupling radiation from different locations of the object (10) to the radiation sensor.