RU2355961C2 - Drying drum with infrared heater - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: drying drum with infrared heater relates to procedure and equipment for continuous drying of long-length materials: wet textile cloth, loom beam after smoothing, paper, fabric, general mechanical rubber goods as well as for heating film materials touching or embracing rotating cylindrical surfaces. A heater in the drum is mounted inside the drum as a fixed axle made in the form of a cylindrical infrared incandescent electric lamp coaxial to the drum and the journals are fitted only with axial bores. An even gap between the lamp bulb and the inner drum surface does not exceed 10 mm, that between the infrared emitters inside the bulb and the inner cylindrical surface of the bulb - 5 mm. There are at least 12 infrared emitters. They are made as straight sections of the spiral which is pulled from the one bulb end face to the other and back in zigzag manner, evenly or unevenly in relation to the circles of their centres, coaxial circle of the bulb.

EFFECT: simplification of design, manufacturing technique, assembly and maintenance, increasing reliability, service life and safety of performance, reduction of energy demand for heating and increasing the uniformity of heating the drum cylindrical wall along its length and circle perimetre.

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Description

The present invention relates to technology and devices for the continuous drying of long materials: wet textile fabric, weaving after sizing, paper; fabric, rubber products, as well as for heating film materials touching or covering rotating cylindrical surfaces, and for drying textile products.

State of the art

Known methods of heating the drying drums by continuously supplying superheated steam to their internal cavity while draining the condensate [1, 2, 3, 4]. The disadvantages of these methods are the difficulty of obtaining and transporting steam, the complexity of the system of removal and disposal of condensate, the need to use large quantities of water suitable for drinking and its treatment.

Known methods of heating the drying drums by using the combustion products of various natural gases as heat carriers, including burning gas mixtures inside the drum [5, 6, 7, 8, 9, 10].

Compared to steam heating, the combustion products of gaseous fuels provide a higher drum heating temperature. The disadvantages of these methods are fire hazard, the complexity of the communications for the supply of combustible gases or hot mixtures after combustion, the environmental hazard of both the combustion products themselves and the condensate. In addition, a large air flow rate and a complex design of nozzles and nozzles inside the drums are necessary for combustion.

A known method of heating the drying drums with an integrated rotating transformer [11]. A transformer with a length equal to the length of the drum, for example three-phase, is placed inside the drum. In this case, the shells from the ends of the drum serve as the active load of the transformer. The transformer, heating, heats the cylindrical shell of the drum.

The disadvantages of this method are low efficiency and high power consumption; the need for complex and cumbersome electrical insulation of all drum parts; high complexity of the design, its installation and assembly, high material consumption.

Known methods of heating the drying drums from the inside by high-frequency currents by placing cylindrical solid or composite inductors with a gap relative to the inner wall of the drum inside the drum on a fixed axis [12, 13, 14, 15].

The most significant drawbacks of these methods are the high complexity of implementation, requiring high-frequency generators, protective screens, etc .; low efficiency; the inability to use lightweight non-ferrous metals or plastics in the manufacture of the drum, in which eddy currents are not induced; high energy intensity of heating and the inability to adjust the temperature.

A known method of contact electric heating of a cylindrical wall from the inside [16, 17].

In this method, a pair of electrodes is heated by a bulk electrically conductive powder placed between them, which, in turn, heats it by contact with the shell of the drum. The implementation of this method is the simplest. The disadvantages include high energy intensity. This is due to the fact that the powder is poured down and can be located only in the lower part of the drum, and the heat of the drum wall should be delivered to the contact zone of the dried material with the cylindrical wall of the drum. The cylindrical wall blown outside by air is continuously cooled, so the powder will be hot and not at all in the drying zone of the web.

In fact, the heating method [18] is similar, where a linear electric heater inside the drum heats the water poured into the lower part of the drum. The disadvantages of this method are the inability to ensure sufficient heating of the cylindrical wall of the drum and small functionality.

When boiling water, steam rising from the water, in contact with the inner cylindrical surface, condenses and flows down, cooling the boiling water. The boiling point of water is known - 100-105 ° С, and its condensate cooling occurs cyclically: water boils → steam settles on the inner wall → collects in drops → condensate drains → water cools, stops boiling → boils again, etc. Its average temperature does not exceed 90 ° C, while according to the technical conditions for drying it should not be lower than 110 ° C.

Limited functionality is due to the fact that heating is carried out only in the lower part of the drum. The material to be dried on a drying machine covers the drum both from below and from above and from the sides [1, 2].

Due to constant contact with heated water and steam, expensive anticorrosive materials, such as stainless steel, are used to make the drum.

Known methods and devices for heating the drying drums from the inside with linear or point sources of directional infrared radiation [19, 20, 21, 22].

These sources are fixedly placed on a fixed axis inside the drum, connecting them to the electrical network through the voltage regulator.

The main disadvantage of these infrared heaters is the great complexity of the design and, therefore, the implementation of heating.

The closest technical solution (prototype) is a drying drum with an infrared heater (IKN), known from [23].

In this heater, emitters of directional IR radiation (incandescent lamps of the type IKZ or IKZK-250), which are point in comparison with the dimensions of the drum itself, are mounted on dielectric strips in electrons and connected by wiring. The strips are placed in the guides with the possibility of moving the strips relative to the guides along the generatrix of the drum. Guide rails are fixedly attached to a fixed axis mounted inside the drum coaxially with it. The fixed axis is installed by the ends in opposite trunnions of the drum by means of non-conductive bearings. The fixed axis is declared hexagonal with flat faces, on which guides for the slats are parallelly fixed along the axis. The electrical wiring from all the slats is brought out of the drum and connected to the mains through the voltage regulator.

This infrared heater is more convenient in operation than the analogues found in the information sources.

Separately, electric lamps of incandescent, infrared radiation (mod. IKZ, IKZK), as well as quartz-halogen lamps of infrared radiation (mod. KGT), commercially available, for example, at OJSC "LISMA" [24], are known.

Each of these lamps individually is a good source of infrared radiation (IRI), however, the power of one such lamp is not enough to heat the dryer drum (SB) from the inside, uniformly along its entire length, to an operating temperature of 140 ° C. Therefore, in the analogues and prototype, the number on the fixed axis inside the drum reaches 45 pieces, 15 pieces in each of the three rows on the slide bar.

Reasons that prevent obtaining technical results:

Great constructive technological complexity and, as a consequence, the complexity of implementing drum heating, the excessive laboriousness of monitoring the heater’s performance.

The complexity is due to the need to manufacture, assemble, install a large number of parts and components of the IKN with their placement inside the SB, coaxial to it.

The excessive laboriousness of monitoring the performance of an IKN is associated with the need to continuously check the electrical resistance (spiral) of each individual electric lamp in it: "burned out - did not burn out." For this, additional resistance diagnostics are required for each line of lamps on the retractable bar. This further increases complexity.

Low reliability and durability of the infrared heater: this is a consequence of the great complexity of the design, especially in terms of the large number of electrical contacts and electrical connections (lamps with lampholders, electric cartridges with cable ends, electric wires with phase and neutral wires). When the SB rotates, its vibrations through the bearings are transmitted to the fixed axis (TSC), exciting vibrations of all its elements in the electrical circuit. Since the currents in the circuit are high (more than 15A), the soldering of its connections is unacceptable, and the binding of wires under the influence of vibration is weakened. There is a real threat of separation of wires, shorting them to mass. This leads not only to the occurrence of an emergency when heating the SB, but also to the risk of electric shock to the operating personnel.

Uneven heating of the cylindrical wall of the drum and excessive energy consumption for heating the cylindrical wall of the drum (high energy intensity): heating of the SB wall inside occurs along the generatrix above the rows of infrared lamps. Between these rows of heating by infrared radiation does not occur. When the SB rotates relative to the fixed rows of individual lamps, its wall emits thermal radiation in the direction of the fixed axis between the rows, giving off heat, i.e. cooling down. Therefore, on the one hand, rapid heating of the wall occurs only opposite to infrared lamps (rows), i.e. unevenly with respect to the circle of the SB, and on the other hand, cooling the wall between the rows requires a significantly higher radiation power of the lamps (or their greater number in the rows) so that the cylindrical wall of the SB does not cool, but heats up to a given temperature. Associated with this is the excessive energy intensity of the known technical solutions.

Signs of the prototype, coinciding with the claimed technical solution: the drying drum with an infrared heater contains a cylindrical body with removable, rigidly connected coaxially axles, provided with external bearings, with the possibility of rotation of the drum, and through axial holes, one of which is equipped with a kinematic sprocket or pulley for rotation the drum, as well as a fixed axis, placed in the axial holes of the pins with the ends by means of bearings and electrically connected on one side through the regulator voltage generator to the mains.

The task of the invention is to obtain the following technical results:

constructive and technological simplification of heating;

increased reliability and durability during operation of the drying drum with an infrared heater;

ensuring uniform heating and reducing energy intensity.

These technical results are in the inventive drying drum with an infrared heater, comprising a cylindrical body with removable, rigidly attached coaxially axles, provided with external bearings, with the possibility of rotation of the drum, and through axial holes, one of which is equipped with a kinematic sprocket or pulley for rotating the drum, and also a fixed axis, placed in the axial holes of the pins with the ends by means of bearings, and electrically connected on one side through a voltage regulator to the electric network, this fixed axis is made in the form of a cylindrical electric infrared incandescent lamp with a glass cylindrical bulb placed coaxially to the drum, with a uniform gap relative to the inner cylindrical surface of the drum body, and the incandescent spiral of the electric lamp is made in the form of a bulb uniformly stretched from one to another inner end surface of the bulb zigzags uniformly or unevenly located on the cylindrical surface of the coaxial flask, in straight sections along its sample the gap between the drum casing and the bulb of the electric bulb does not exceed 10 millimeters, and the gap between the straight sections of the zigzags and the inner cylindrical surface of the bulb does not exceeds 5 millimeters, and the number of straight sections is not less than 12, and the trunnions have only axial holes.

The essence of the invention is illustrated by drawings, where

figure 1 schematically shows a longitudinal section of the inventive drying drum with an infrared heater (with a cylindrical infrared incandescent lamp);

figure 2 similarly shows a cross section of a drum;

figure 3 similarly shows the construction of the basement of the infrared lamp;

Fig. 4 likewise shows the cylindrical spike of the bulb of the bulb opposite the cap.

The diagrams and drawings show:

1 - a cylindrical housing of the drying drum (SB), hereinafter referred to as the housing,

2A, 2B, respectively, the right and left trunnion SB, rigidly connected to the housing 1 by a detachable connection, for example screws (not indicated in the drawings),

3 - outer bearings of the right 2A and left 2B pins, the outer rings of which are motionlessly mounted in a fixed frame 4 SB,

4 - bed SB,

5 - fixed cylindrical infrared lamp (cylindrical glass bulb of the lamp, hereinafter referred to as the bulb), replacing the fixed axis of the prototype,

5A - the base of the bulb 5 of an electric lamp with electric terminals for an electron cartridge, for example E27,

5B - an electron cartridge, for example E27,

5B is a cylindrical spike of the flask 5,

6 - incandescent spiral lamp 5 (5, 5A, 5B), made of an alloy based on chromium,

6A - straight sections of the zigzags of the spiral 6,

6B - curved sections of the zigzags of the spiral 6,

7 - ceramic thin-walled disks made of heat-resistant dielectric ceramics, hereinafter referred to as disks,

7A - through holes in the disk 7, uniformly made on the periphery of the disks 7,

7B - spike of the disk 7, coaxial to the disk 7,

8 - external metal reinforcement (for example, steel) from the ends of the flask 5,

9 - electrical terminal 5A,

10, 11 - metal contacts of the electrical terminals 9 of the cap 5A under the cartridge, for example E27,

12 - bearings of an electric lamp 5 (bulb 5),

13 - flask retainer 5,

14 - kinematic sprocket transmission of torque to the SB,

15 - voltage regulator,

16 - electrical wiring of the connection of the regulator 15 with the electric cartridge 5A.

In the drawings and diagrams are indicated:

W _VP - the width of the dried fabric VP,

Ш _ИКИ - the width of the infrared emitters of the lamp 5,

V _VP - the linear velocity of the VP web to be dried on the SB,

ω ₁ - the angular velocity of rotation of the SB with the housing 1,

31 - the gap between the inner surface of the housing 1 and the outer surface of the cylindrical flask 5,

32 - the gap between the inner surface of the flask 5 and the straight sections 6A of the spiral 6.

Short names:

IKN - infrared heater.

IKI - infrared emitter (s).

SB - dryer drum.

The inventive drying drum with an infrared heater operates as follows.

When you turn on the drive of the dryer drum machine (not shown) through a chain drive (not shown) through the sprocket 14 of pin 2B, the dryer drum with housing 1 rotates at an angular speed of ω ₁ in its own bearings 3 relative to the stationary bed 49 (Fig. 1, 2).

Pre-inserted in the pins 2B and 2A SB, respectively, with a spike 5B and a cap 5A, a cylindrical, glass, infrared glow lamp with bulb 5 coaxially to the housing 1 on its own bearings 12 and is fixed motionlessly by a latch 13 (Fig. 1). An electric lamp 5 (5A, 5B), 6 (6A, 6B), 7 (7A, 7B), 8, 9, 10, 11 are connected to an electrons (for example, E27), which is wired 16 to the output of the voltage regulator 15 (for example, single-phase LATR). The input of the regulator 15 is connected to a single-phase power supply ≅ 220B.

In this form, the bulb 5 of the electric lamp is a fixed axis fixed by the latch 13, electrically connected through a voltage regulator to the electrical network.

At the same time as the drive is turned on, an electric voltage is supplied to the input of the regulator 15, setting it to the maximum output voltage. From the output of the regulator 15 through the wiring 16 through the cartridge 5B (figure 1) through the electrical contacts 10, 11 and electrical conclusions 9 (figure 1, 3) of the cap 5A of the electric lamp 5, 5A. 5V, electric current enters spiral 6 (6A, 6B), heating its straight 6A and 6B curved sections of zigzags to a temperature of 2500 ± 200 ° C (At this temperature, the electromagnetic radiation of a red-hot spiral corresponds to the infrared spectrum, i.e. 10 ¹² -10 ¹⁴ Hz. In addition, the lamp was prefabricated according to standard technology: it is tight, air is removed from the internal cavity, glass is optically transparent for the IR radiation spectrum).

The spiral 6 inside the bulb 5 of the lamp is evenly stretched from the right end surface of the bulb 5 to the left and back, on the edges of round, flat, thin ceramic discs 7 with axial spikes 7B with which they are firmly fixed (filled into the glass of the cap 5A and the bulb spike 5B inside the bulb 5) at opposite ends of the flask 5, facing each other with smooth surfaces, coaxial to the flask 5 and parallel to each other. Along the perimeter of the disks 7, with a uniform gap from their bounding circles, small through circular holes 7A are made uniformly or unevenly around the circumference, covering their centers with the coaxial flask 5. A spiral 6 is passed through these holes 7A, forming straight sections 6A in a zigzag fashion, uniformly stretched and based on the circular edges of the disks 7, parallel to the axis SB and curved sections 6B on the inner surfaces of the disks 7, as shown in Fig.2. The number of straight sections 6A corresponds to the number of holes 7A, and the number of curved 6B sections is half as much.

The straight sections 6A of spiral 6 heated by passing electric current are infrared emitters (IRI). This IR radiation, directed through the cylindrical surface of the flask 5, directionally heats the wall of the housing 1 from the inside to a predetermined temperature, after which the rotating housing 1 is bent around the dried web VP, which, adjacent to the housing 1 (figure 2), is heated. Moving from one to another SC (FIGS one shown), with a linear velocity V _sn and more hot gas, a VI dried. VP can be impregnated with dressing weaving in bulk on sizing machines of weaving; wet layer of paper pulp on paper machines; fabric impregnated with a latex solution in the manufacture of a card tape (rubber production); polymer film; damp cloth after dyeing, etc.

A cylindrical glass infrared glow lamp (5-11) in serial production is a typical component of an electrotechnical product, as well as a typical 5B electric cartridge. External steel reinforcement 8 with steel base parts 5A, 5B and the ends of the electric bulb on the outside increases the strength and wear resistance of its base 5A and spike 5B (FIGS. 3 and 4), especially when installed in bearings 12 (FIG. 1).

Compared with the prototype and analogues, one single cylindrical infrared glow lamp 5 is the only part of one infrared heater (IKN) for one SB.

This achieves the first technical result of the present invention is a constructive and technological simplification of the security system with an integrated circuit tens of times.

The absence of electrical wiring, electrical cartridges, electrical connections and electrical contacts inside a rotating SB (in the field of high temperatures and vibrations) makes this technical solution ideally reliable, durable and safe, which achieves the second technical result of the invention. The straight sections 6A of the spiral 6, stretched between the disks 7, behave similarly to a stretched string during vibrations, i.e. cannot touch each other.

The achievement of the third technical result is ensured automatically and is illustrated by comparing the electrical parameters of the prototype and the claimed SB with TSC on the example of a drying drum of a sizing machine mod. ШБ-11/180 [1] (11 SB, SB working length 1.8 m, total length 2 m, outer diameter 0.57 m, SB radial runout ± 2.5 mm, operating temperature 140 ° C or 415K, W _VP - the width of the dried weaving Navoi 1.8 m).

In the prototype IKN there can be no more than six rows of IKZK-250 lamps, the diameter of which is 125 mm. On the length of the SB 2000 mm, in the prototype, in one row, 16 lamps can be placed on the bar along the generatrix of the SB. The total length of the spiral of one lamp IKZK-250, in the form of a half ring - 50 mm. The plane of this half-ring is located at a distance of 35 mm from the surface of the bulb opposite the base (closest to the inner surface of the SB). Structurally, the gap between this surface of the bulb and the inner cylindrical surface of the rotating SB cannot be less than 10 mm. Therefore, the IKI of the IKZK-250 lamp (spiral) is located at a distance of at least 45 mm from the inner surface of the drum. In the curled technical solution, IKI (direct stations 6A) are located at a distance of no more than 15 mm, i.e. 3 times closer. It is known that the energy (and power) of radiation is inversely proportional to the square of the distance [25, p. 185, “Illumination E of a flat surface created by a point source”], therefore, the intensity of heating the drum wall by radiation in the prototype at the same electric power is 9 times weaker than in the claimed SB with IKN.

In six rows of 16 lamps IKZK-250 of the prototype, the total number of lamps is 96, and the total length of the IKI (at 50 mm in one) is 4.8 meters.

The total length of one straight section of the IKI in the claimed SB with TSC (minus two meters of the length of the SB, the thickness of the ends of the flask 5 with reinforcement 8 - 10 mm on each side, disks 7 - 5 mm to each end, total 30 mm) is 1700 mm or 1.7 m. With a minimum number of IKI (12 pieces, sections 6A, FIG. 2) in the claimed SB with IR, the total length of the IRB inside the SB is 20.4 meters, which is almost 5 times more than in the prototype.

It is especially important that each IRI in a row (straight section 6A) is a uniformly distributed emitter (in contrast to the point prototype) along the wall of the housing 1, and the emitters (straight sections 6A) are twice more evenly distributed around the circumference of the coaxial inner cylindrical surface of the housing 1 . This provides at least two times greater uniformity of heating the walls of this housing 1.

Due to the significantly longer length of the spiral 6 (6A, 6B) than in the prototype, its electrical resistance R is also significantly larger. Since it is known that W = U ² / R, where W is the electric power and U is the electric voltage [25, p. 130, “Operation of electric current”], it becomes clear that to heat the housing 1 to the operating temperature and to maintain this temperature when working SB (with the same working electrical voltage U) consumes significantly less power than in the prototype.

Given the fact that the IKI (in the claimed technical solution) is three times closer to the building 1, and the IKI is 4.25 times longer, the energy consumption of heating of the claimed SB with an ICI is 5-6 times less.

An important advantage of the claimed electromechanical device (SB with IKN) is that there is no need to make additional through holes in the walls of the trunnions, except for the main axial one (unlike the prototype, in which additional windows are required for inserting and removing strips with lamps inside the drum). This not only simplifies the manufacture of the drum, but also reduces the energy consumption of heating, since the air heated inside the drum does not go outside, and the surrounding cold does not enter the drum.

It should be noted that the size of the gaps s1 and s2 (figure 2) is limited to the smaller side: for s1 - the total radial runout during rotation of the SB of the inner cylindrical surface of the housing 1 for s2 - the melting temperature (thermal destruction) of the glass of the bulb 5.

Information sources

1. Zhivetin V.V.A. and Brut-Bruljako A.B. Design and maintenance of sizing machines. M., Legprombytizdat, 238 p.

2. Patent of Russia No. 2037588, cl. D20B 21/00, publ. 06/19/95.

3. US patent No. 4949475, CL. F26B 13/16, 08.21.1990.

4. UK patent No. 1238757, CL F26B 13/14.

5. Copyright certificate of the USSR No. 1605085, class. F26B 13/06, publ. 1991 year

6. USSR author's certificate No. 579689, cl. F26B, publ. 1979 year

7. US patent No. 4683015, CL. F26B 3/24, 1987.

8. Copyright certificate of the USSR No. 118224, cl. F26B 1972

9. Patent of Russia No. 2027131, cl. F26B 13/14, publ. 01/20/95.

10. Patent of Russia No. 2137996, class. F26B 13/14.

11. USSR author's certificate No. 90517, cl. F 26 B 13/14 (claimed 08/20/1948, publ. 1959).

12. Copyright certificate of the USSR No. 220744, cl. D21F 5/02, 1952

13. British patent No. 2227823A, CL. F26B 13/14.

14. USSR copyright certificate No. 731234, cl. F26B 13/18, publ. 04/30/80

15. Patent of Russia No. 2177129, cl. F26B 13/18, publ. 12/20/2001

16. Copyright certificate of the USSR No. 514177, cl. F16B 13/18, publ. 05/15/76.

17. Germany patent No. 1226287, NKI 39a ³ 7/14, 1966

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21. RF patent No. 2263730 IPC D06B 15/00; F26B 13/00, priority 05/14/2004 "A method for heating a drying drum, for example, a sizing machine, from within with linear infrared emitters of limited length" Published on November 10, 2005 Bull. No. 31.

22. RF patent No. 2299730, IPC F26B 13/18; Priority 04/26/2004. "A method for heating a drying drum, for example, a sizing machine," published on 02/10/2006 Bull. Number 4.

23. FIPS decision of 04/26/2006 on the grant of a patent of the Russian Federation on application No. 2004133244/06 (036063), IPC F26B 13/00; priority 12.11.2004. "Drying drum sizing machine with infrared heater."

24. E-mail, E-mail: lisma@moris.ru (http://www.lisma-vavsholding.ru//lisma-saransk.ru).

25. Koshkin N.I., Shirkevich M.G. Handbook of elementary physics. M., Science, 1976

Claims (1)

A drying drum with an infrared heater, comprising a cylindrical body with removable, rigidly attached coaxial axles equipped with external bearings, with the possibility of rotation of the drum and through axial holes, one of which is equipped with a kinematic sprocket or pulley for rotating the drum, and also a fixed axis, placed in the axial holes of the pins with ends by means of bearings and electrically connected on one side through a voltage regulator to an electrical network, characterized in that this The fixed axis is made in the form of a cylindrical electric infrared incandescent lamp with a glass cylindrical bulb placed coaxially with the drum with a uniform gap relative to the inner cylindrical surface of the drum body, and the incandescent spiral of the electric lamp is made in the form of zigzags uniformly stretched from one to the other end surface of the bulb, uniformly or unevenly located on the cylindrical surface of the coaxial flask, in straight sections along its generators, with uniform or a non-uniform gap between these sections of zigzags around the circumference and with a uniform gap relative to the inner cylindrical surface of the bulb, in addition, the radial clearance between the drum body and the bulb of the lamp does not exceed 10 mm, and the gap between the straight sections of the zigzags and the inner cylindrical surface of the bulb does not exceed 5 mm, and the number of straight sections is at least 12, and the pins have only axial holes.

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