前苏联专利SU938738A3 Air cooling unit for die plate with orifices

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专利摘要:
In an apparatus for producing glass fibers wherein an orifice plate formed with a greater number of orifice holes in high density is provided to draw glass fibers therethrough and air nozzle means is provided for impinging air flow against the undersurface of the orifice plate so that the adjacent cones of molten glass formed on the undersurface of the orifice plate may be prevented from coalescing to each other, an air nozzle assembly is provided which includes a plurality of tubular nozzles arranged in such a way that their discharge ports may be arranged in line and in parallel with the longitudinal direction of the array of orifice holes in the orifice plate and spaced apart from each other by a predetermined distance. High cooling efficiency may be attained with a less consumption of cooling air; the undersurface of the orifice plate may be uniformly cooled; the operation for separating a bead of molten glass formed on the undersurface of the orifice plate into individual cones may be facilitated; and the filament or fiber breakage due to the impingement of the air jets may be avoided.
公开号:SU938738A3
申请号:SU772537149
申请日:1977-10-28
公开日:1982-06-23
发明作者:Соно Хироаки；Исикава Синзо；Вакаса Исао
申请人:Нитто Босеки Ко Лтд(Фирма)；
IPC主号:

专利说明:

393 nominal consumption of cooling air. This goal is achieved by the fact that in an air cooling unit of a spinnere plate with holes, including nozzles arranged in one row parallel to the spin plate, individually connected to an air source, the nozzles are made with an outlet size larger than a quarter of the width of the nozzle plates. The cross section of each nozzle is round. The cross section of the outlet of each nozzle is made in the form of an ellipse or in the form of a cross section bounded by two parallel sides of equal length and convex or elliptical curves connecting the ends of the sides. The distance between the centers of adjacent outlets is three times smaller than their small axis. FIG. J is a cross-sectional view of a glass fiber manufacturing apparatus using an air cooling unit, front view; in fig. 2 - the same, side view; on fig.Z installation unit air cooled eeni, front view; in fig. 4 - the same, rear view; in fig. 5, an air cooled air cooling unit, top view, the cross section of each nozzle being round; in fig. 6 - the same, with the cross-section of the outlet of each nozzle made in the form of an ellipse. The device for the production of fiberglass works as follows. The molten glass 1 fed from the feeder flows down through the perforated screen 2 into the glass melter. Electric current is supplied to the current leads 3 in order to maintain the appropriate temperature in the glass melter. The molten glass in the feeder flows through a multitude of holes 4 in the spinneret plate 5 and enters the atmosphere, forming a multitude of individual strands 6. which are mechanically drawn downwards. At the same time, the air jets created by the air cooling unit act on the outer surface of the phiper plate 5 with the holes. In order to prevent the connection of the adjacent cones of molten glass formed on this surface. The air cooling unit N contains a plurality of tubular nozzles 7, which are preferably mounted on the support 3 in one row parallel to each other. which are inserted into the holes 10 and secured in them with set screws 11, screwed into the holes 12, made in the support 8 and provided with a thread. In the central portion located on the rear surface of the support 8, there are a plurality of threaded holes 13 that are used to attach the air cooling unit N to the mounting bracket 9, which moves the N unit up and down, back and forth, left and right, and also rotating it, so that the unit of air nozzles N can be installed in an optimal position relative to the nozzle plate 5- The lower ends of the tubular nozzles 7 are connected to hoses 14, which are connected to a source of compressed air (there is no shown). The jets of air coming out of the nozzles 7 are directed upwards and cool the stretchable threads and cones, the molten glass on the outer surface of the spin plate 5, and also affect the spin plate 5 to cool it. Typically, the spinneret plate 5 is rectangular, and the number of holes therein is more than 800, so the outlet openings of the tubular nozzles 7 are located parallel to one of the long sides of the spinneret plate 5 and are spaced apart from each other by a certain distance. The tubular nozzles have a circular cross section and are preferably made of metal, for example copper, aluminum, brass, steel or stainless steel (Fig. 5). The optimum cooling effect is provided by the cross section of tubular nozzles 7 from 40 to 100 mm. If the cross-sectional area is too small, some areas of the spin plate 5 will be subjected to excessive cooling, as a result of which an uneven temperature distribution on the surface of the spin plate 5 will be created. If the cross section area of the nozzles is too large, satisfactory cooling will not be achieved. and the air flow rate must be increased to compensate for poor cooling. However, if the air flow in the cooling jet is increased too much, the stretching of the thread will be deflated and deflected, and the cones of molten glass on the outer surface of the spinneret plate 5 will tend to join together, with the result that the strands may break. Preferably, the distance between the axes of adjacent tubular nozzles 7 is as short as possible, however, the smaller the distance; between the axles of the nozzles 7, the pain ;. will be the number of nozzles 7. installed on the support 8, and, therefore, no more air flow. The proposed air cooling unit has the following advantages: 1. As compared with the known nozzles, it provides the operator with an opportunity to separate and separate the threads from the stuck together cones of molten glass faster and easier on the outer surface of the spin plate 5. 2. A higher cooling efficiency is achieved air nozzles with less air flow. 3. The filler plate is cooled evenly. . Bending of the glass strands is virtually eliminated, leading to rupture of the strands. 5. The air cooling unit is a simple design, the investigator, it can be made simpler cheaper. Example 1. For comparison, the well-known nozzle with the following dimensions of output outlet would be used: Length, mm 198 Width, mm 7 Cross-sectional area, mm Number of supply tubes, pcs. Dimensions of the proposed air cooling unit: Internal diameter, mm Cross-sectional area, mm Number of nozzles, pcs. Total cross-sectional area, mm Pitch (distance between nozzles), mm These nozzles were used together with a nozzle plate, the following dimensions: Width, mm 32, Length, mm 200.7 Number of holes in the nozzle plate, pcs. 2000 Productivity, g / min 800 Test results are given in Face 1. Table 1
Split time, min
Temperature distribution over the spin plate
Air consumption required to reduce the temperature of the die plate per m / min
Yarn deflection
± 3
1.5 Minor Example: three spinnerets / Three air-cooled units A, B and C were prepared, which Q were used respectively with
The air cooling blocks cool the spin plate well and evenly, so that the glass fibers can be pulled out continuously.
With a circular cross section of the tubular nozzles, the spun filter plate is satisfactorily cooled in the longitudinal direction. However, uniform cooling of the spin plate in the transverse direction can only be achieved if the diameter of the tubular nozzle is more than a quarter of the width of the mesh of holes in the spin plate, i.e. if the diameter of the nozzles is less than a quarter of the width of the mesh of holes in the spinneret plate, the holes located in the zone that is not affected
air jets are not cooled sufficiently, and the cones of molten glass in these holes tend to connect. To eliminate this drawback, tubular nozzles with an elliptical cross section are used.
Tubular nozzles of elliptical cross section can be made by compressing tubular circular nozzles, heating them in dies, or directly passing them through dies designed to give elliptical sections to nozzles.

权利要求:
Claims (2)
[1]
The advantages of nozzles of elliptical cross section are as follows: the number of holes in the spinneret plate in the transverse direction can be 79387388 2. Prepared, the dimensions of which are given plates A, B, and i.e. 2. Table 2 by splined plates A, B and C, the dimensions of which are given in table. 3. 993 increased; The air jets act on the die plate with great force with a small amount of air flow, thereby achieving a higher cooling efficiency. Claim 1, an air cooling unit for a spin plate with holes, including nozzles arranged in one row parallel to a spin plate, individually connected to an air source, characterized in that, to increase cooling efficiency with minimum air consumption, the nozzles are sized outlet hole, a large quarter of the width; Holes spin plate. 2. The unit according to claim 1, distinguished by the fact that the cross-section of each nozzle is round. 3. The block according to claim 1, is also distinguished by the fact that the cross section of the outlet of each nozzle is made in the form of an ellipse or in the form of a cross section bounded by two parallel sides of equal length and convex or elliptical curves connecting the ends of the sides. . The block according to claim 3 is also distinguished by the fact that the distance between the centers of the adjacent outlets is three times smaller than their small axis. . Sources of information taken into account in the examination 1. US patent number 3905790, cl. 65-2, 1975.
[2]
2. US patent If 3986853, cl. 65-2, 1976.
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同族专利:

公开号 | 公开日

IN147883B|1980-08-02|

IT1091081B|1985-06-26|

ES463676A1|1978-08-01|

NL171256B|1982-10-01|

GB1573546A|1980-08-28|

BE860240A|1978-02-15|

PT67216A|1977-11-01|

DE2747034A1|1978-09-14|

NL7711899A|1978-09-13|

DK479777A|1978-09-12|

TR19672A|1979-10-05|

PT67216B|1979-03-26|

FR2383139B1|1980-12-19|

DE2747034B2|1981-01-29|

MX145221A|1982-01-14|

NL171256C|1983-03-01|

US4159200A|1979-06-26|

ZA776089B|1978-07-26|

BR7707226A|1978-09-26|

CS210669B2|1982-01-29|

DE2747034C3|1981-12-03|

JPS5433293B2|1979-10-19|

NZ185416A|1981-05-01|

SE7712128L|1978-09-12|

JPS53114927A|1978-10-06|

AU499537B1|1979-04-26|

CA1097921A|1981-03-24|

FR2383139A1|1978-10-06|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE2420650A1|1974-01-14|1975-07-24|Edward Thomas Strickland|METHOD AND DEVICE FOR MANUFACTURING FIBER GLASS FIBER|

US3986853A|1975-08-08|1976-10-19|Kaiser Glass Fiber Corporation|Control system for the drawing of glass fibers|

US4033742A|1976-02-13|1977-07-05|Kaiser Glass Fiber Corporation|Method for producing glass fibers|

US4003731A|1976-04-26|1977-01-18|Owens-Corning Fiberglas Corporation|Nozzle for fluids|US4202680A|1978-10-16|1980-05-13|Owens-Corning Fiberglas Corporation|Fluid flow apparatus in combination with glass fiber forming apparatus|

US4362541A|1981-04-27|1982-12-07|Owens-Corning Fiberglas Corporation|Method and apparatus for producing glass fibers or filaments|

US4391619A|1981-10-14|1983-07-05|Nitto Boseki Co., Ltd.|Air nozzle apparatus for use in drawing glass fibers|

US5205851A|1990-10-12|1993-04-27|Sumitomo Electric Industries, Ltd.|Method and apparatus for producing optical fiber coupler|

US6267328B1|1999-10-21|2001-07-31|Rohr, Inc.|Hot air injection for swirling rotational anti-icing system|

US7320581B2|2003-11-17|2008-01-22|Aktiengesellschaft Adolph Saurer|Stabilized filament drawing device for a meltspinning apparatus|

US7172398B2|2003-11-17|2007-02-06|Aktiengesellschaft Adolph Saurer|Stabilized filament drawing device for a meltspinning apparatus and meltspinning apparatus including such stabilized filament drawing devices|

EP3445712A4|2016-05-30|2020-01-01|Adven Industries, Inc.|Activated carbons with high surface areas and methods of making same|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

JP2693577A|JPS5433293B2|1977-03-11|1977-03-11|

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