WO2011046473A2 - Electric heating device - Google Patents

Abstract

The invention relates to a device that comprises an electric heating member (1) included in an envelope (2) made of a heat-resistant electrically insulating material, and attached to a heat-radiation means made of a soft magnetic material. The device includes outputs (3, 4) for connection to a power supply network (11) and to the ground (12). The heat radiation means comprises a panel (5) on one side of which the electric heating member (1) included in the envelope (2) is attached, while the other side comprises a coating (6) that increases the radiation capacity coefficient of the panel (5). The electric heating member (1) comprises a heating conductor (7), and the envelope (2) consists of a silicone insulation (8). The conductor (7) is connected in zigzag with one side of the panel (5) by an aluminium adhesive strip (9), and the other side of the panel (5) comprises a coating (6) that increases the radiation capacity coefficient thereof. In another embodiment, the device comprises a box-shaped housing (13) that comprises a front cover (14) defining a heat-radiation means and a back cover (15), the covers being connected together so as to define a chamber (16) in which are arranged an electric heating member (17) oriented towards the front cover (14) and a heat insulation material (18) oriented towards the back cover (15).

Description

 ELECTRIC HEATING DEVICE

 Technical field

 The present invention relates to electric power, and more specifically to an electric heating device.

 State of the art

 Known electric heating device (certificate for utility model .4 ° 10969 from 08.16.1999), containing two electrical insulating plates. On the first plate, on one side is an electric heating element. The electric heating element is connected to the first plate by flashing it on the other side with a cotton thread. The first plate is connected to the second plate by a heat-resistant flame-retardant polymer.

 When using this electric heating device, an alternating electromagnetic field is formed in the surrounding space, which has an adverse effect on biological objects. This is because the lead-in conductors, together with the electric heating element, form a sufficiently large emitting AC circuit in area, while there is no grounded shield. The degree of exposure is determined by the parameters of the electric heating device, as well as the time and proximity of being near this electric heating device.

 Known electric heating device (patent for utility model N ° 15827 from 06/19/2000) containing a resistive electric heating element enclosed in a shell made of heat-resistant electrically insulating material. The resistive electric heating element is made in the form of a flat electric heater and together with the shell is enclosed in a closed casing, which is made of magnetically soft sheet steel and tightly compresses the electric heating element on both sides. The resistive electric heating element has terminals for connecting to the mains, and the casing has a terminal for connecting to ground.

When heated, the front side of the electric heating device is subject to thermal deformations caused by the fact that in this design, the middle of the front side of the electric heating device is always hotter than its peripheral part and the end walls forming thermal “cold bridges”. This leads to warping and swelling of the middle of the front side electric heating device. Which, in turn, eliminates the possibility of applying decorative finishing materials to the front side of the electric heating device. In addition, it is impossible to install insulating material inside the electric heating device, which excludes the possibility of using this device, for example, in heating furniture or window sills.

Disclosure of invention

 The basis of the present invention is to prevent warping and swelling of the middle part of the front side of the electric heating device, which makes it possible to apply various decorative finishing materials to the front side of the electric heating device, as well as expand the scope of the proposed device, for example, for use in heating furniture, in window sills and things like that.

 This problem is solved by creating an electric heating device containing an electric heating element enclosed in a shell made of heat-resistant electrically insulating material and mounted on a means for thermal radiation made of magnetically soft material, while the device has conclusions for connecting to a power supply network and for connecting to ground, moreover, according to the invention, the means for thermal radiation is a panel, on one side of which is attached for prison the sheath electric heating element, and the other side has a coating that increases the ability of the panel radiator coefficient.

The technical result of the invention is to simplify and cheapen the design and manufacturing technology of the proposed electric heating device, as well as expanding the scope of the proposed device, for example, for use in heating furniture, in window sills and the like. This eliminates warping and swelling of the middle part of the front side of the electric heating device. Which, in turn, makes it possible to apply various decorative finishing materials to the front side of the electric heating device. In addition, the electrical and fire safety of the electric heating panel increases and there are practically no electromagnetic fields emitted by the panel (in tens of times less than the maximum permissible).

 It is advisable that the coating, increasing the emissivity of the panel, was a coating of powder paints of various colors. This makes it possible to produce inexpensive heating panels in which the requirements for interior design are simplified. The proposed electric heating panel is not afraid of dents on the front side, while there are practically no electromagnetic fields emitted by the panel.

 To facilitate use in heated furniture, it is desirable that the panel has a curved shape.

 It is favorable that the electric heating element is a heating wire, and the shell is a silicone insulation, while the heating wire enclosed in silicone insulation is zigzag placed on one side of the panel and attached to it by means of aluminum adhesive tape. This makes it possible to perform the proposed device of various predetermined sizes and specific power.

 It was found that the best results in terms of the efficiency / power ratio of the means for thermal radiation are achieved if the heating wire is made of nichrome wire, the length and cross section of which are selected from the ratios:

15m ^"1 <L / S <25M ^"1; Where:

 L is the length of the nichrome wire m;

 "

 S is the area of the heating panel, m;

@ = h * S * L * P _ya / U ² ; Where:

@ - cross section of a nichrome wire m ² ;

 h is the resistivity of the nichrome wire ohm * m;

R _y d - specific thermal power of the panel W / m;

 U is the supply voltage of the heating element, V.

It is possible that the enclosed electric heating element is a film heater made of two glued layers of electrical insulation material such as lavsan, between which an electric heating element is fixed or applied by spraying, while one sheet on the outside has an adhesive coating, through which the shell is attached to the panel . In this case, for the manufacture of typical mass production panels, the electric heating element can be a layer of resistive material placed between these two sheets in a zigzag fashion, and can be a layer of resistive material made in the form of many strips, essentially parallelly fixed by their ends on two opposite conductive conductors.

 The problem is also solved by the fact that an electric heating device containing an electric heating element enclosed in a shell made of heat-resistant electrically insulating material and mounted on a means for thermal radiation made of magnetically soft material, while the device has conclusions for connecting to a power supply network and for connecting to ground, and, according to the invention, the device comprises a casing made in a box shape and containing a front cover, which is a means for thermal radiation, and a back cover fastened together to form a cavity in which an electric heating element facing the front cover is located, and heat-insulating material facing the back cover, while the front cover on the outside has a coating that increases the coefficient its emissivity.

 The technical result of the proposed utility model is to simplify and cheapen the design and manufacturing technology of the proposed electric heating device, and also expands the scope of the proposed device, for example, for use in heating furniture, in window sills and the like. This eliminates warping and swelling of the middle part of the front side of the electric heating device. Which, in turn, makes it possible to apply decorative finishing materials to the front side of the electric heating device.

It is advisable that the coating, which increases the emissivity of the front cover, is a coating of powder paints of various colors. This makes it possible to produce inexpensive heating panels in which the requirements for interior design are simplified. The proposed electric heating panel is not afraid of dents on the front side, while there are practically no electromagnetic fields emitted by the panel. To reduce heat loss through the back cover, it is favorable that the insulating material is a foamed insulating material selected from the group: polyurethane foam, polyethylene foam, polystyrene foam, mineral wool, basalt wool, taken individually or in combination.

 It is possible that stiffeners are made on the front cover from the outside. In this case, it is advisable that the stiffeners are protrusions made across the front cover essentially parallel to each other. This allows you to strengthen the front side of the heating panel, and also eliminates the membrane effect (clicking when heating and cooling), especially manifested on large surfaces of the heating panel.

 Preferably, the stiffeners are recesses made across the front cover essentially parallel to each other. This allows to apply stone finishing materials, such as marble mosaics or small ceramic tiles, on the front side.

 To relieve thermal stresses in large-sized devices, it is favorable that notches are made on the front cover along its perimeter and between the stiffeners, while it is good that the notches are made in at least two rows in a checkerboard pattern. This makes it possible in large-sized devices to eliminate the bulging of the central region of the electric heating device, which is warmer with respect to the peripheral part. In addition, this makes it possible to glue the heat emitter of a large electric heating device with marble and granite slabs and, thus, produce heated marble and granite window sills and countertops.

 It is advisable that the first layer of adhesive composition, then a layer of material having anti-deformation properties, then a second layer of adhesive composition, then a layer of ceramic tile or mosaic are placed on the front cover from the outside.

The use of an intermediate layer of material with anti-deformation properties, for example, such as special mats from DITRA, allows gluing stone finishing materials to deformable substrates, and also provides reliable waterproofing. This allows you to make heating panels and products from them, used in moist and damp rooms, such as heated massage tables, heated stone seats and chaise longues.

 To isolate parts of the device from visual perception, it is desirable that an end profile is fixed on the end side of the electric heating device, which covers all the elements of the electric heating device on the side. Such a constructive implementation is used for the manufacture of heated window sills, where only one end bounding profile is required, which can be made of aluminum alloy in the form of a decorative border.

 It was established that the best results in terms of the efficiency / power ratio of the emitter are achieved if the electric heating element is made of nichrome wire, the length and cross section of which are selected from the relations:

15m ^"1 <L / S <25m ^"1; Where:

 L is the length of the nichrome wire m;

S is the area of the heating panel, m ² ;

@ = h * S * L * P _yfl / U ² ; Where:

@ - cross section of a nichrome wire m ² ;

 h is the resistivity of the nichrome wire ohm * m;

R _beats - specific thermal power of the panel W / m;

 U is the supply voltage of the heating element, V;

 The technical result achieved by this useful model is the ability to apply any, including ceramic and stone finishing materials, having a wide range of design solutions, having a high coefficient of thermal radiation and having a therapeutic effect, for example, when used in heating furniture (stone therapy) heated window sills and slopes located under the window sills, decoratively designed for the interior of rooms, heating devices.

In addition, the technical result of the proposed utility model is to simplify and cheapen the design and manufacturing technology of the proposed electric heating device, and the scope of the proposed device is expanding, for example, for use in heating furniture, in window sills and the like. This eliminates warping and swelling of the middle part of the front side of the electric heating device. Which, in turn, makes it possible to apply decorative finishing materials to the front side of the electric heating device.

 Brief Description of the Drawings

 For a better understanding of the present utility model, specific examples of its implementation are given below with reference to the accompanying drawings, in which:

 Figure 1 schematically depicts a first embodiment of an electric heating device made according to the invention;

 FIG. 2 - AA in FIG. 1;

 FIG. 3 is a second embodiment of an electric heating device made according to the invention;

 FIG. 4 is a third embodiment of an electric heating device made according to the invention;

 FIG. 5 - BB - in FIG. four;

 FIG. 6 is a fourth embodiment of an electric heating device made according to the invention;

 FIG. 7 - BB in FIG. 6;

 FIG. 8 is a fifth embodiment of an electric heating device made according to the invention;

 FIG. 9 - GG in Fig 8;

 FIG. 10 is a first embodiment of a front cover of an electric heating device according to the invention;

 FIG. 1 1 - DD in FIG. 10;

 FIG. 12 - EE in FIG. 10;

 FIG. 13 is a second embodiment of a front cover of an electric heating device according to the invention;

 FIG. 14 - MF in FIG. 13 with a ceramic layer placed on the front cover;

FIG. 15-3-3 in FIG. 13 with a ceramic layer placed on the front cover;

FIG. 16 is a third embodiment of a front cover of an electric heating device according to the invention;

 Fig.17 - II in Fig.16 with a ceramic layer placed on the front cover;

FIG. 18 is a fourth embodiment of the front cover electric heating device made according to the invention.

 The best embodiment of the invention

 The proposed electric heating device can be presented in various versions of its implementation.

 For example, figure 1 and figure 2 shows the most structurally simple electric heating device containing an electric heating element 1, enclosed in a shell 2 made of heat-resistant electrically insulating material, and mounted on a means for thermal radiation made of soft magnetic material, for example, steel. The device has conclusions 3, 4 for connecting to a power supply network and for connecting to ground (not shown in the drawing). The means for thermal radiation is a panel 5, on one side of which an electric heating element 1 enclosed in a casing 2 is attached, and the other side has a coating 6 that increases the emissivity of the panel 5. The electric heating element 1 enclosed in a casing 2 is a film heater made of two glued layers of electrical insulation material such as lavsan, between which an electric heating element 1 is fixed or applied by spraying, while one sheet with the outer side has an adhesive coating, through which the shell is attached to the panel 5. Basically, the above-described electric heating devices are used with the seats and backs of heated furniture.

 In FIG. 3 schematically shows a second embodiment of an electric heating device, in which the panel 5 has a curved shape for use in ergonomic heating furniture, for example, an armchair.

 For the manufacture of typical panels of mass production, the electric heating element 1 can be a layer of resistive material placed between two sheets in a zigzag pattern, and can be (Fig. 4, 5) a layer of resistive material made in the form of many strips 11, essentially parallelly fixed at their ends on two opposite current-carrying conductors h.

Coating 6, is a coating of powder paints of various colors. Powder coating increases the emissivity of panel 5. approximately three times. This allows to produce inexpensive heating panels 5, in which the requirements for interior design are simplified. The proposed electric heating panel 5 is not afraid of dents on the front side, while there are practically no electromagnetic fields emitted by the panel 5.

 Another embodiment of the proposed utility model is possible, for example, shown in FIG. 6, 7. In this embodiment, the electric heating element is a heating wire 7, and the sheath is a silicone insulation 8, while the heating wire 7 enclosed in a silicone insulation 8 is zigzag placed on one side of the panel 5 and attached to it by an aluminum adhesive tape 9. This makes it possible to perform the proposed device of various predetermined sizes and specific power. Enclosed in silicone insulation 8, the heating wire 7 at each end has a sealed coupler 10 connected to the power cable of the power supply network 1 1 with grounding 12.

 It was found that the best results in terms of the efficiency / power ratio of the means for thermal radiation are achieved if the heating wire 7 is made of nichrome wire, the length and cross section of which are selected from the ratios:

15m ^"1 <L / S <25m ^"1; Where:

 L is the length of the nichrome wire m;

S is the area of the heating panel, m ² ;

@ = h * S * L * P _yfl / U ² ; Where:

 @ - cross section of a nichrome wire m;

 h is the resistivity of the nichrome wire ohm * m;

R _beats - specific thermal power of the panel W / m ² ;

 U is the supply voltage of the heating element, V.

The above-described embodiments of the proposed utility model simplify and reduce the cost of the design and manufacturing technology of the proposed electric heating device, and also expand the scope of the proposed device, for example, for use in heating furniture, in window sills and the like. This eliminates warping and swelling of the middle part of the front side of the electric heating device. Which, in turn, makes it possible to apply on the front side electric heating device decorative decorative materials. In addition, this makes it possible to carry out the proposed device of various predetermined sizes and specific power for individual performance under a specific order. The pitch and cross section of the heating wire depend on the specified specific power.

 In yet another embodiment of the proposed utility model shown in FIG. 8, 9, the electric heating device comprises a casing 13 made in a box shape and comprising a front cover 14, which is a means for thermal radiation, and a rear cover 15, fastened together to form a cavity 16 in which the heating element 17 is located, enclosed in a shell, made of heat-resistant electrically insulating material, and facing the front cover 14, and heat-insulating material 18, facing the back cover 15, while the front cover 14 on the outside has a coating 19, The decreasing coefficient of its emissivity.

 The box-shaped form of the casing 13 can be used for the manufacture of simple electric heating devices with an area of 0.3 sq. m to 0.7 sq.m.

 Coating 19, which increases the emissivity of the front cover 14, is a coating 19 of powder paints of various colors. Coating 19 of powder paints increases the emissivity of the front cover 14 by approximately three times. This makes it possible to produce low-cost electric heating devices in which the requirements for interior design are simplified. The proposed front cover 14 is not afraid of dents on the front side, while there are practically no electromagnetic fields emitted by it.

 The heat-insulating material 18 is a foamed heat-insulating material selected from the group: polyurethane foam, polyethylene foam, polystyrene foam, mineral wool, basalt wool, taken individually or in combination. This provides a reduction in heat loss through the back cover 15.

 On the front cover 14, stiffeners 20 can be formed on the outside.

The ribs 20 can be protrusions 21 (Fig. 10, 1 1, 12), made across the front cover 14 essentially parallel to each other. This allows you to strengthen the front side of the electric heating device, and also eliminates the membrane effect (clicking when heating and cooling), especially manifested on large surfaces of the electric heating device.

 The development trend of heating systems in a modern home is aimed not only at energy saving, but also at increasing comfort and even the healing properties of heat.

 The treatment with warm stone, the so-called "stone therapy", has long been known and is widely used. The beneficial effect on the human body of radiant heat emanating from the warm wall of a brick heating stove, as well as from stoves and fireplaces with brick pipes lined with tiled ceramic tiles, is known.

 Since furnace heating is not used in a modern house, it is possible to replace it with an electric heating device, in which the ribs 20 are recesses 22 (Figs. 13, 14, 15), made across the front cover 14 essentially parallel to each other. This allows you to increase the rigidity of the front cover, which makes it possible to apply stone finishing materials, such as marble mosaics or small ceramic tiles, to the front side.

 To remove thermal stresses in large-sized devices (Fig. 16), notches 23 are made on the front cover 14 around its perimeter and between the stiffeners 20, while the notches 23 can be stitched in at least two rows. This makes it possible in large-sized devices to eliminate the bulging of the central region of the electric heating device, which is warmer with respect to the peripheral part. In addition, this makes it possible to glue the front cover 14 of the large electric heating device with marble and granite slabs and, thus, produce, for example, heated marble and granite window sills and countertops.

 On the front cover 14 (Fig. 17), on the outside, a first adhesive layer 24 is placed, then a layer 25 of material having anti-deformation properties, then a second adhesive layer 26, then a layer of ceramic tile or mosaic.

The use of an intermediate layer of material having anti-deformation properties, for example, such as special mats made by DITRA, allows gluing stone finishing materials to deformable substrates, and also provides reliable waterproofing. This allows you to make electric heating devices and products from them, used in wet and damp rooms, such as heated massage tables, heated stone seats and stove benches in bathhouses.

 On the end side of the electric heating device, an end profile 28 can be fixed (Fig. 18), which covers all the elements of the electric heating device from the side. Such a constructive implementation is used for the manufacture of heated window sills, where only one end bounding profile is required, which can be made of aluminum alloy in the form of a decorative border.

 The technical result achieved by this useful model is the ability to apply any, including ceramic and stone finishing materials, having a wide range of design solutions, having a high coefficient of thermal radiation and having a therapeutic effect, for example, when used in heating furniture (stone therapy) heated window sills and slopes located under the window sills, decoratively designed for the interior of rooms, heating devices.

 In addition, the technical result of the proposed utility model is the simplification and cheapening of the design and manufacturing technology of the proposed electric heating device, and the scope of the proposed device is expanding, for example, for use in heating furniture, in window sills and the like. This eliminates warping and swelling of the middle part of the front side of the electric heating device. Which, in turn, makes it possible to apply decorative finishing materials to the front side of the electric heating device.

 The proposed electric heating device operates as follows.

In all embodiments, the electric heating device operates in the same way.

When voltage is supplied to the terminals of an electric heating device, the electric heating element ensures uniform heating of the front side of the panel or the front wall of the casing throughout area. The grounding of the electric heating device ensures its electrical and fire safety.

 Industrial applicability

 This utility model can be used for heating residential, office, industrial and other premises. To create hot-air barriers in the vestibules, porches, halls and the like. For heating damp and wet rooms: car washes, greenhouses, basements, bathrooms, showers, laundry rooms and the like. For mobile transport: cabins, cabins, vans, wagons and the like. The use of this utility model in preschool, educational and medical facilities is very effective. Due to the highest degree of electrical protection, the proposed utility model is ideal for heating and heating pools of any design, both built-in and open.

Claims

FORMULA

1. An electric heating device containing an electric heating element (1) enclosed in a shell (2) made of heat-resistant electrically insulating material and mounted on a means for thermal radiation made of magnetically soft material, while the device has conclusions (3, 4) for connecting to power supply network and for connecting to ground, with the fact that the means for thermal radiation is a panel (5), on one side of which is attached enclosed in a shell (2) electron successive element (1) and the other side has a coating (6) increasing the radiative panel capacity factor (5).

 2. An electric heating device according to claim 1, characterized in that the coating (6), which increases the emissivity of the panel (5), is a coating (6) of powder paints of various colors.

 3. An electric heating device according to claim 2, characterized in that the panel (5) has a curved shape.

 4. The electric heating device according to claim 1, characterized in that the electric heating element is a heating wire (7), and the sheath (2) is a silicone insulation (8), while the heating wire enclosed in silicone insulation (8) ( 7) is zigzag placed on one side of the panel (5) and attached to it by means of aluminum adhesive tape (9).

 5. Electric heating device according to claim 4, characterized in that the heating wire (7) is made of nichrome wire, the length and cross section of which are selected from the ratios:

15m ^"1 <<25m ^"1; Where:

 L is the length of the nichrome wire m;

S is the area of the heating panel, m ² ;

@ = * S * L *? _ya / ² ; Where:

 @ - cross section of a nichrome wire m;

 h is the resistivity of the nichrome wire ohm * m;

R _uD - specific thermal power of the panel W / m;

U is the supply voltage of the heating element, V.

6. An electric heating device according to claim 1, characterized in that the electric heating element (1) enclosed in a shell (2) is a film heater made of two glued layers of electrical insulation material such as lavsan, between which an electric heating element is fixed or applied by spraying (1), while one sheet on the outside has an adhesive coating by which the sheath (2) is attached to the panel (5).

 7. The electric heating device according to claim 6, characterized in that the electric heating element is a layer of resistive material placed between two sheets in a zigzag pattern.

 8. An electric heating device according to claim 6, characterized in that the electric heating element (1) is a layer of resistive material made in the form of a plurality of strips (li), essentially parallelly fixed with their ends on two opposite conductive conductors (b).

 9. An electric heating device containing an electric heating element (17) enclosed in a shell made of heat-resistant electrically insulating material and mounted on a means for thermal radiation made of soft magnetic material, while the device has conclusions (3, 4) for connecting to a power supply network (11) and for connecting to ground (12), characterized in that the device comprises a casing (13), made box-shaped and containing a front cover (14), which is a means for thermal and radiation, and the back cover (15), bonded to each other with the formation of a cavity (16) in which the electric heating element (17) is located, facing the front cover (14), and heat-insulating material (18) facing the back cover (15) while the front cover (14) on the outside has a coating (19) that increases its emissivity.

 10. An electric heating device according to claim 9, characterized in that the coating (19), increasing the emissivity of the front cover (14), is a coating (19) of powder paints of various colors.

11. An electric heating device according to claim 9, characterized in that the heat insulating material (18) is a foamed heat insulating material selected from the group: polyurethane foam, polyethylene foam, polystyrene foam, mineral wool, basalt wool, taken individually or in combination.

 12. An electric heating device according to claim 9, characterized in that the ribs (20) of rigidity are made on the front cover (14) from the outside.

 13. An electric heating device according to claim 12, characterized in that the stiffening ribs (20) are protrusions (21) made across the front cover (14) substantially parallel to each other.

 14. An electric heating device according to claim 12, characterized in that the stiffening ribs (20) are recesses (22) made across the front cover (14) substantially parallel to each other.

 15. An electric heating device according to claim 14, characterized in that notches (23) are made on the front cover (14) along its perimeter and between the ribs (20).

 16. An electric heating device according to claim 15, characterized in that the notches (23) are made in at least two rows in a checkerboard pattern.

 17. An electric heating device according to any one of paragraphs 9-16, characterized in that on the front cover (14), on the outside, a first adhesive layer (24) is placed, then a layer (25) of a material having anti-deformation properties, then the second layer (26) of adhesive composition, then the layer (27) of ceramic tiles or mosaics.

 18. An electric heating device according to claim 9, characterized in that an end profile (28) is fixed on the end side of the electric heating device, which covers all the elements of the electric heating device from the side.

 19. An electric heating device according to claim 9, characterized in that the electric heating element (17) is made of nichrome wire, the length and cross section of which are selected from the relations:

15m ^"1 <L / S <25M ^"1; Where:

 L is the length of the nichrome wire m;

S is the area of the heating panel, m ² ;

@ = h * S * L * P ^ / U ² ; Where:

@ - cross section of a nichrome wire m ² ;

 h is the resistivity of the nichrome wire ohm * m;

R _beats - specific thermal power of the panel W / m;

 U is the supply voltage of the heating element, V.