RU35939U1 - Electric infrared heater (options) - Google Patents

Description

v-5 --- 7 N 05 V 3/40, F 24 D 13/00

Electric infrared heater

The utility model relates to the field of electrical engineering, namely to devices for electric heating (heating) due to infrared radiation, and can be used to heat rooms both industrial and domestic with people, animals, plants, as well as in various fields of science and technology, the national economy for heating various products and materials, for the recovery of liquids both from the surface and from the volume of products and materials (drying), for polymerization, etc.

Known radiant heater (certificate for utility model No. 12314, IPC Н 05 В 3/40, publ. 07/05/1999), containing a heating unit installed in the housing, reflective and heat-insulating elements, the housing is made with a C-shaped cross-section, supporting end lids and a central support, the heating unit is made in the form of a tubular electric heater mounted on the end caps of the housing. The reflective element is placed outside the housing and is made of heat-conducting material in the form of a plate with heat-transferring grooves parallel to the outer plane, and the plate has a variable cross section from the center to the lateral longitudinal edges. The heat transfer grooves are made of various shapes, and the reflective element can be made of various heat-conducting materials.

Known electric radiant heater (options) (certificate for utility model No. 24065, IPC N 05 3/40, F 24 D 13/00, publ. 11/09/2001), containing an electric heater, a heat-emitting element, including a holder in which is installed (options)

electric heater, light plate and reflector. The heat-emitting element has fastening elements on its non-radiating side, made in the form of protrusions along its longitudinal edges. A groove is made in each protrusion, the grooves being located towards each other or opposite to each other. Fasteners in the form of profile brackets or in the form of a profile with a N-like cross section are fixed on the reflector.

Known electric radiant heater (options) (certificate for utility model No. 24066, IPC N 05 B 3/40, F 24 D 13/00, publ. 11/09/2001), containing an electric heater, a heat-emitting element including a holder in which is installed an electric heater, and a radiating plate and a reflector. The heat-emitting element is provided with a cover and fastening elements made along the longitudinal edges, in which the cover is installed and there are two fasteners that are mounted on the reflector and on the ends of the radiating plate or cover.

Known izl atelier (certification for a useful mode.gP) No. 7476, IPC F 24 F 3/16, publ. 08/16/98), containing a spiral placed in a hollow casing, the outer surface of which is coated with a layer that converts thermal energy to infrared radiation, the inner surface of the casing is made with a second converting layer of a given composition, and the surface layers of the casing are made of ceramic material.

The closest in technical essence and adopted for the prototype (option 1) is a sterilizerheater (RF patent No. 2121626, IPC F 24 C 7/04, F 24 F 3/16, publ. 10.11.98), containing a housing placed in it, at least one IR emitter, which contains converters according to the number of heaters, each of which is made in the form of a shell covering the corresponding heater.

The outer and inner transforming shell layers are made of each respective composition.

The closest in technical essence and adopted for the prototype (option 2) is a device for heat distribution (certificate for utility model No. 13130, IPC Н 05 В 3/30, publ. 08/17/1999), including a heating unit installed in the housing, reflective and heat insulating elements. The radiating element is equipped with a form-retaining device (frame) rigidly fixed to the housing, which is made in the form of a box-shaped holder with a U-shaped cross section.

Known radiant heaters allow you to intensify room heating and can be used to heat objects of various configurations, however, design features of the heater have a significant impact on the heating efficiency. In known models, in spite of the effect achieved, the radiation energy loss from the source to heating the body, reflector, and other heater parts is quite significant. This is due to the fact that almost 50% of the radiation energy from the source is directed to the heater body. It is known that heat transfer from a heated body is carried out by convection, heat conduction and radiation. The radiation fraction in these energy losses is significant, since it is proportional to the fourth degree of the temperature of the heated body, and in convection and heat conduction the losses are proportional only to the first degree.

The technical result, which is achieved by the claimed utility model, is to increase the radiation efficiency of the heater by optimizing the performance of the heater elements, increase the density of the heat flux, reduce the cost of consumed electric energy to warm the room to a given temperature, and

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expanding the arsenal of technical equipment for electric heating systems and heating various objects during drying, polymerization and other technological operations, increasing the reliability and service life of the heater.

By radiation efficiency is meant the ratio of energy converted to radiation to the supplied energy. In addition to the directivity of the radiant flux, the value of the black factor of the surface of the emitting body E affects the value of the radiation efficiency. It is known that the main requirement for ensuring effective heat transfer by radiation is the high emissivity of the surface. For example, at the same temperature, an aluminum plate generates a radiant flux of a density 5 times lower than a ceramic plate and 4 times lower than a cast iron / V.Z. Gurevich Electric infrared emitters M., Gosenergoizdat, 1963 /.

The technical result is achieved by the fact that the electric infrared heater (option 1) contains a heat insulating element installed in the housing, a reflector, a heat-emitting unit including at least one tubular radiator with an electric heater located inside it, with its end sides the tubular radiator is installed in holders that fastened to the reflector by fastening elements, the reflector is rigidly attached to the housing. The emitter holders are made in the form of cups with spring elements securing the emitter, the cups have holes in which the electric heater wires and ring grooves are inserted, into which the plugs of the fastening elements are inserted, the holders are rigidly fixed during assembly by crimping their ends. The fastening elements of the holders are made in the form of a fork at one end, the other end is rigidly fixed to the reflector.

The technical result is achieved in that the electric infrared heater (option 2) comprises a heat insulating element located in the housing, a heat-emitting unit and a reflector mounted on the frame, the housing is made in the form of a box with removable end caps, the heat-emitting unit includes at least one tubular radiator with the electric heater located inside it, with its end sides, the tubular radiator is installed in the holders. The frame is made in the form of a longitudinal plate with two pairs of end plates, or two parallel longitudinal plates combined by two pairs of end plates. The emitter holders are installed in the holes of the inner end plates and fixed to them by fastening elements, and the end caps of the housing are fixed to the outer end plates. The emitter holders are made in the form of cups with spring elements fixing the radiator, the cups have openings for the output of the electric heater wire and ring grooves into which the plugs of the fastening elements are inserted, which firmly fix the holders during assembly by crimping their ends. The fastening elements of the emitter holders are made in the form of a plug at one end and are rigidly attached by the other end to the inner end plates of the frame. The inner end plates of the frame have support flanges for installing the reflector.

According to the first and second options:

A heat-insulating element is installed between the housing and the reflector. The air gap between the reflector and the heat insulating element is at least 3 mm.

Tubular emitters are made of materials with an emissivity of at least 0.7.

The holders of the tube emitters are made of electrically insulating heat-resistant material.

The reflector is made in the form of a flat plate bent in the middle across the axis of the emitters at an angle of 3 to 12 degrees, or with a profile cross section, in the form of a parabola.

The reflector or its surface layer is made of material with an emissivity of not more than 0.3

The reflector or its surface layer is made of non-ferrous metals with an emissivity of not more than 0.3.

The reflector or its surface layer is made of non-ferrous alloys with an emissivity of not more than 0.3.

The reflector or its surface layer is made of structural polymers with an emissivity of not more than 0.3.

The reflector or its surface layer is made of polymers with an emissivity of not more than 0.3.

The heat-insulating element is made of structural heat-resistant polymers with a thermal conductivity of not more than 0.06 W / ().

The heat-insulating element is made of heat-resistant mineral materials with a thermal conductivity of not more than 0.06 W / ().

The heat-insulating element has a material shielding from radiation on the reflector side with a radiation coefficient of not more than 0.3, for example, from foil.

The heater has a guard on the side of the tubular emitters in the form of a coarse-mesh rigid grid fixed to the body.

In FIG. 1 shows a general view of the heater (option 1). Figure 2 presents a longitudinal section of a heater (option 1). On Fig 3 presents a General view of the heater (option 2). Figure 4 presents a view aa of Fig. 3 (option 2). On Fig.3 presents a view of BB of Fig.Z (variait 2). In FIG. 6 is a partial sectional view of the attachment of the tubular emitter in the holder (options 1 and 2).

Where: 1 - building; 2 - heat insulating element; 3 - reflector; 4 one or more tubular emitters; 5 - electric heaters; 6 holders; 7 - fasteners; 8 - a layer of foil on a heat-insulating element 2; 9 - spring elements; 10 - holes; 11 - electric heater wires 5; 12 - annular grooves on the holder 6; 13 - removable fence (coarse mesh); 14 - removable end covers of the housing 1; 15 - longitudinal plates of the frame; 16 - outer end plates of the frame; 17 - inner end plates of the frame; 18 holes; 19 - supporting flanges.

An electric infrared heater (option 1) contains (Fig. 1) a housing 1, a heat-insulating element 2, a reflector 3, a heating element, and includes one or more tubular emitters 4 with electric heaters located inside 5. The tube emitter 4 (tubular emitters) is installed at the end sides in the holders 6 (Fig. 2), which are fixed to the reflector 3 by fastening elements 7. The fastening elements 7 of the holders 6 are made in the form of a fork at one end, the other end is rigidly fixed to the reflector 3. The reflector 3 is rigidly attached to the housing 1. The holders 3 (Fig. 6) of the emitter 4 are made of insulating, heat-resistant material (for example, ceramic) and are made in the form of cups with spring elements 9 fixing the tubular emitter 4. The cups have holes 10 into which wires 11 of the electric heater 5 are led and annular grooves 12, into which the plugs of the fastening elements 7 are inserted, the rigidly fixing holders 6 during assembly by crimping their ends. The heat-insulating element 2 can be supplemented with a layer of material 8 with high reflection properties (for example, foil). The heater has a removable fence 13 in the form of a coarse rigid mesh fixed to the housing 1 from the side of the tubular emitters 4.

An electric infrared heater (option 2) contains (Fig. H) a housing 1, a heat-insulating element 2, a heat-emitting unit and a reflector 3. The housing 1 is made in the form of a box with removable end caps 14, the heat-emitting unit includes one or more tubular emitters 4 with inside them with electric heaters 5. The end faces of the tubular emitters 4 are installed in the holders 6. The heat-emitting unit is mounted on a frame installed in the housing 1 (Fig. 4), made in the form of two parallel longitudinal plates 15 volume internal two pairs of end plates - the outer 16 and the inner 17. The longitudinal plates 15 can be made in the form of two U-shaped brackets that are fastened together by the outer plates 16, and to which the inner plates 17 are rigidly attached. The holders 6 of the tubular emitters 4 are installed in holes 18 of the inner end plates 17 (Fig. 5) and are fastened to them by fastening elements 7. The fastening elements 7 of the holders 6 are made in the form of a fork at one end and are rigidly attached by the other end to the inner end plates 17 of the frame. The removable end caps 14 of the housing 1 are attached to the outer end plates 16. Hold; w 6 (Fig. B) are made in the form of cups with spring elements 9 fixing tubular emitters 4, cups have openings 10 for outputting wire 11 of electric heater 5 and ring grooves 12, into which the plugs of the fastening elements 7 are inserted, the rigidly fixing holders 6 during assembly by crimping their ends. The inner end plates 17 of the frame have support flanges 19 for installing the reflector 3. The tubular emitters 4, the reflector 3 and the heat-insulating element 2 are fixed on the inner end plates 17, placed inside the housing 1 and together with the guard 13 by a coarse mesh, are fastened together by removable covers 14, which are fixed on the extra-wide end plates 16.

Tubular emitters 4 are made of materials with an emissivity of at least 0.7 and are, for example, quartz or metal tubes.

The reflector 3 can be made in the form of a flat plate bent in the middle perpendicular to the axis of the emitters at an angle of 3 to 12 degrees, or a sheet having a profile (for example, parabolic) cross section. Reflector 3 or its surface layer can be made of: non-ferrous metals (for example, gold, silver, aluminum, copper, zinc, nickel, etc.) and their alloys; from structural or reinforced polymers; from conductive and / or heat-conducting materials with high reflection properties and, accordingly, with a radiation coefficient of not more than 0.3.

In the described heater model, the reflector 3 can be made of aluminum of the AO, A5, AD1 grades, aluminum-magnesium alloy AMg or other materials with an emissivity of not more than 0.3 and subject the outer (working) surface of the reflector from the side of the tube emitters 4 to polishing. The source of thermal radiation (electric heater 5) can be a spiral made of a precision alloy with high electrical resistivity (for example, from nichrome, tungsten, etc.), placed in a quartz or metal tube made of a material with an emissivity of at least 0.7 (tube emitter 4 ) As an element of protection against touching heated elements of the device, you can use the fence 13 (coarse metal mesh), mounted on the housing 1 from the side of the tubular emitters 4.

The thermal conductivity of the heat-insulating element 2 of heat-resistant structural polymers or mineral materials should not exceed 0.06 W / (). The heat-insulating element 2 can be supplemented on the reflector side by a radiation-shielding layer 8 of

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material with an emissivity of not more than 0.3 (i.e., a layer of material with high reflection properties, for example, foil).

In the claimed utility model, the tubular emitter 4 is made of a material with a high coefficient (not less than 0.7), and the reflector 3 or its surface layer is made of a material with an emissivity of not more than 0.3 (i.e., with high reflection properties and low black ratio). With this embodiment, the operating life of the electric heater is increased, the tubular radiator 4 can have a higher temperature, which increases the fraction of thermal energy from the electric heater 5 converted into, and additionally the redistribution of the flow values in the surrounding space occurs. The fraction of radiation from the reflector 3, directed inside the heater and lost when the heat-insulating element 2, the housing 1 and other parts is undesirably heated, decreases by 4-5 times and the proportion of radiation in the direction of the heated objects in the room increases, which increases the heating efficiency. In addition, to reduce the above-mentioned losses, the reflector 3 and the heat-insulating element 2 are separated by an air gap of at least 3-5 mm. For example, the installation of only one screen (reflector) with a degree of blackness, 1 between the heat source and the casing, reduces the radiant heat transfer by about 14 times / M.A. Mikheev, I.M. Mikheeva Fundamentals of heat transfer M., Energy, 1973 /.

The implementation of the electric infrared heater

of the proposed design and from materials with the specified emissivity allows you to evenly distribute heat in the irradiation zone of the object with a higher flux density of infrared radiation with the same supplied electric power with other heaters. As a result, the flux density can be provided on the irradiated surface to 1, OW / sq. Cm, the heating time is reduced

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material or product to the required temperature and various technological processes can be performed in which heating up to 200,250 ° C is necessary. The constructive implementation of heaters improves their reliability and service life.

The increased heat flux density in the direction of the irradiated object allows you to expand the arsenal of technical means and the scope of their application in electric heating systems and / or heating of various objects during drying, polymerization and other technological operations, for example, when drying paints and varnishes on painted surfaces of various products.

Thus, in contrast to the known electric heat sources, the proposed model converts up to 93% of the thermal energy received from the electric heater into the radiant infrared stream directed at the consumer. Heated elements of the device are protected from touch. If the heater is suspended at a certain height under the ceiling, the heat flux density is ensured at the level of the solar constant (0.135 W / sq. Cm), lower energy consumption is required for heating the room to a given temperature, and it can be used for heating both residential and industrial premises.

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Claims (33)

1. An electric infrared heater comprising a heat-emitting unit, a reflector, a heat-insulating element installed in the housing, characterized in that the heat-emitting unit includes at least one tubular radiator with an electric heater located inside it, with its end sides the tube radiator is mounted in holders that are fixed to the reflector with fasteners, the reflector is rigidly attached to the housing. 2. The electric infrared heater according to claim 1, characterized in that the emitter holders are made in the form of cups with spring elements fixing the tubular radiator, the cups have openings into which electric heater wires and ring grooves are inserted into which fastening elements are fixed holders during assembly by crimping their ends. 3. Electric infrared heater according to claim 1 or 2, characterized in that the fastening elements of the holders are made in the form of a plug at one end, the other end is rigidly fixed to the reflector. 4. Electric infrared heater according to claim 1, characterized in that the insulating element is installed between the housing and the reflector, while the air gap between the reflector and the insulating element is at least 3 mm. 5. The electric infrared heater according to claim 1, characterized in that the tubular emitter or tubular emitters are made of materials with an emissivity of at least 0.7. 6. Electric infrared heater according to claim 1 or 2 and 3, characterized in that the emitter holders are made of electrically insulating heat-resistant material. 7. Electric infrared heater according to claim 1 or 3 and 4, characterized in that the reflector is made in the form of a flat plate bent in the middle across the axis of the emitters at an angle of 3 to 12 °. 8. Electric infrared heater according to claim 1 or 3 and 4, characterized in that the reflector is made with a profile cross section. 9. Electric infrared heater according to claim 1 or 7 and 8, characterized in that the reflector or its surface layer is made of material with an emissivity of not more than 0.3. 10. Electric infrared heater according to claim 1 or 7 to 9, characterized in that the reflector or its surface layer is made of non-ferrous metals with an emissivity of not more than 0.3. 11. Electric infrared heater according to claim 1 or 7 to 9, characterized in that the reflector or its surface layer is made of non-ferrous alloys with an emissivity of not more than 0.3. 12. Electric infrared heater according to claim 1 or 7 to 9, characterized in that the reflector or its surface layer is made of structural polymers with an emissivity of not more than 0.3. 13. Electric infrared heater according to claim 1 or 7 to 9, characterized in that the reflector or its surface layer is made of reinforced polymers with an emissivity of not more than 0.3. 14. Electric infrared heater according to claim 1 or 4, characterized in that the heat-insulating element is made of structural heat-resistant polymers or heat-resistant mineral materials with a thermal conductivity of not more than 0.06 W / (m · K). 15. Electric infrared heater according to claim 1 or 4, or 14, characterized in that the heat-insulating element has on the reflector side a layer of material shielding from radiation with an emissivity of not more than 0.3, for example, foil. 16. Electric infrared heater according to claims 1 or 2-15, characterized in that it has a fence in the form of a coarse-mesh rigid grid mounted above the tubular emitters and fixed to its body. 17. An electric infrared heater comprising a heat insulating element installed in the housing, a heat emitting unit and a reflector mounted on a frame, characterized in that the housing is made in the form of a box with removable end caps, the heat emitting unit includes at least one tubular emitter located inside electric heater, with its end faces the tubular radiator is installed in the holders, the frame is made in the form of a longitudinal plate with two pairs of end plates or two parallel ial longitudinal plates, combined with two pairs of end plates, radiators holders installed in the openings inner end plates and secured thereto mounting elements and end caps are fixed to the outer casing of the end plate. 18. Electric infrared heater according to claim 17, characterized in that the holders are made in the form of cups with spring elements fixing the tubular emitter, the cups have openings for the output of the electric heater wire and ring grooves into which the plugs of the fastening elements are inserted, rigidly holding the holders during assembly by crimping their ends. 19. An electric infrared heater according to claim 17 or 18, characterized in that the fastening elements of the holders of the tubular emitter are made in the form of a plug at one end and are rigidly attached by the other end to the inner end plates of the frame. 20. The electric infrared heater according to claim 17, characterized in that the inner end plates of the frame have supporting flanges for installing the reflector. 21. The electric infrared heater according to claim 17, characterized in that the heat insulating element is installed between the housing and the reflector, while the air gap between the reflector and the heat insulating element is at least 3 mm. 22. The electric infrared heater according to claim 17, characterized in that the tubular emitter or tubular emitters are made of materials with an emissivity of at least 0.7. 23. Electric infrared heater according to claim 17 or 18 and 19, characterized in that the emitter holders are made of electrically insulating heat-resistant material. 24. Electric infrared heater according to claim 17 or 20 and 21, characterized in that the reflector is made in the form of a flat plate bent in the middle across the axis of the emitters at an angle of 3 to 12 °. 25. Electric infrared heater according to claim 17 or 20 and 21, characterized in that the reflector is made with a profile cross section. 26. An electric infrared heater according to claim 17 or 24 and 25, characterized in that the reflector or its surface layer is made of material with an emissivity of not more than 0.3. 27. Electric infrared heater according to claims 17 or 24-26, characterized in that the reflector or its surface layer is made of non-ferrous metals with an emissivity of not more than 0.3. 28. Electric infrared heater according to claims 17 or 24-26, characterized in that the reflector or its surface layer is made of non-ferrous alloys with an emissivity of not more than 0.3. 29. Electric infrared heater according to claims 17 or 24-26, characterized in that the reflector or its surface layer is made of structural polymers with an emissivity of not more than 0.3. 30. Electric infrared heater according to PP.17 or 24-26, characterized in that the reflector or its surface layer is made of reinforced polymers with an emissivity of not more than 0.3. 31. Electric infrared heater according to claim 17 or 21, characterized in that the heat-insulating element is made of structural heat-resistant polymers or heat-resistant mineral materials with a thermal conductivity of not more than 0.06 W / (m · K). 32. Electric infrared heater according to claims 17 or 21, 31, characterized in that the heat-insulating element has a layer of material shielding from radiation from the side of the reflector with an emissivity of not more than 0.3, for example, foil. 33. Electric infrared heater according to claims 17 or 18-32, characterized in that it has a fence in the form of a coarse-mesh rigid grid mounted above the emitters and fixed to its body.