JPS58163557A - Producing device for foil piece - Google Patents

Abstract

PURPOSE:To improve production efficiency by projecting many small faces of the same circumference on the outside circumferential surface of a heat collecting drum which rotates at a high speed, supplying a molten metal like a belt thereto and enabling the formation of a foil piece. CONSTITUTION:A titled device consisting of a heat collecting drum 10, a rotating device 11 for rotating the drum 10 at a high speed and a nozzle 12 extending in the axial direction of the drum 10, and a melting device 13. The outside circumferential surface 16 of said drum 10 is divided to a plurality by ring grooves 15 which are continuous in the circumferential direction. Many small faces 6 which are made discontinuous by steps are formed on the respective divided outside circumferential parts. The molten material 2 flowing from the nozzle 12 continuously like a belt onto the outside circumferential surface of the drum 10 from the nozzle 12 is supplied from the device 13.

Description

DETAILED DESCRIPTION OF THE INVENTION This invention provides a heating drum having an outer circumferential surface (=a large number of facets and rotating at high speed), which supplies a molten material in two continuous strips, At the same time, the centrifugal force of the heat collecting drum (: therefore, the foil pieces are scattered and peeled off).
: relates to an apparatus for producing foil pieces directly from molten material.

Conventionally, elongated solid products (hereinafter referred to as filaments) are used.

) directly from molten material, for example, the one shown in Figures 1 and 2 (Japanese Patent Publication No. 52
-22898).

This manufacturing device includes a cooling member 1 with a V-shaped cross section and a plurality of semicircular grooves 1b (thus discontinuing the outer peripheral edge 1a), a rotating device (not shown) for rotating the cooling member 1 at high speed, The cooling member 1 (consisting of a melting device (not shown) that melts and supplies the bifilament material. Then, the molten material 2 is supplied from above to the tip of the outer peripheral edge 11L of the rotating cooling member 1, and the cooling member 1 Then, the heat of the supplied molten material 2 is extracted to solidify at least a part of the molten material 2, and the molten material 2 is scattered by the centrifugal force of the cooling member 1 and peeled off from the outer peripheral edge 1. By continuously performing this step, a filament 3 having a length corresponding to the length of one section of the outer peripheral edge separated by the groove 1b is obtained.
can be manufactured in large numbers in succession. Note that the length of the filament 3 can be made shorter as the length of one section of the outer peripheral edge of the cooling member 1 is made shorter.

However, since the filament manufacturing apparatus (2) as the preceding technique described above supplied the molten material 2 in a linear form to the rotating cooling member 1, only one filament 3 could be manufactured at a time. Therefore, the production efficiency was not fully satisfactory.Moreover,
Due to the structure of the outer peripheral edge 1a of the cooling member 1, the solid product that can be manufactured is limited to the elongated filament 3C.

This invention was made in view of these conventional problems, and an object of the invention is to directly (= produce) a large number of foil pieces from molten material at once, and to
It is another object of the present invention to provide a foil piece manufacturing device that can continuously manufacture a large number of foil pieces. An object of the present invention is to provide a foil piece manufacturing device that is easy to manufacture and has high production efficiency.

Therefore, as in the embodiments shown in FIGS. 3 to 11, the outer circumferential surface is divided into a plurality of parts in the axial direction (both 4 and 4) by means of ring grooves 15 continuous in the circumferential direction. Each divided outer circumferential surface portion 16 (2) is discontinuously formed by a stage 5 to form a large number of small surfaces 6 in the heat collecting drum 10.
, a rotating device 11 for rotating the heat collecting drum 10 at a high speed, and a nozzle 12 extending in the axial direction of the heat collecting drum 10, and a molten material 2 from the nozzle 12.
and a melting device 13 that continuously supplies the molten material 2 to the outer peripheral surface of the heat collecting drum 10 by flowing out the material 2 in a band shape.

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

FIGS. 3 to 8 are diagrams showing one embodiment of the present invention. First, to explain the structure, numeral 10 shown in FIGS. 3 to 7 is a heat collecting drum which is a cooling member. , is divided into a plurality of parts in the axial direction.The ring groove 15 (=therefore, each divided outer peripheral surface part 16 has a heat collecting drum 10 as shown in an enlarged view in FIGS. 5 to 7). A V-shaped groove 4 extending parallel to the axial direction of (Then, the same number of facets 6 as the number of steps 5 is formed. That is, one side of the groove 4 forms steps 5,
The outside of this step 5 intersects with one edge 9 of the facet 6, and
The outside of the other side of the groove 4 meets the other edge of the facet 6.

therefore.

The edge 9 extends parallel to the axial direction of the heat collecting drum 10. The small surface 6 is a curved surface having a radius of curvature of the outer diameter of the heat collecting drum 10. The cross-sectional shape is semicircular (C2) as shown in FIG.

As an example of a specific configuration of the heat collecting drum 10, for example, the outer circumferential surface is divided in advance into a plurality of ring grooves 15 (2, thus a predetermined number of parts), and then each of the divided outer circumferential surface portions 16 The stage 5 (2) forms a large number of discontinuous facets 6 (2).The material of the heat collecting drum has high thermal conductivity, such as a copper-chromium alloy, and Abrasion (2) Material (2) is formed, and if necessary (2) cooling channels etc. are provided inside to efficiently collect heat from the molten material (2). .

Reference numeral 11 shown in FIG. 362 is a rotating device for rotating the heat collecting drum 10 at high speed.
is composed of an electric motor, a transmission, and other well-known equipment, and this rotating device 11 is connected to the heat collecting drum 10.
Shaft 10 & Kimi 2 are connected. In this way, the outer peripheral surface of the heat collecting drum 10 (the circumference and speed of the two small surfaces 6 provided by the rotating device 11) are freely controlled at high and low speeds. A box body 22 is installed below the heat collecting drum 10, and this box body 2
2 (2) Foil pieces 23 scattered and peeled off from each small surface 6 of the heat collecting drum 10 are accumulated and housed. Face 6
This is a wiper for wiping away the foil pieces 23 that remain attached to the surface.

Further, 13 shown in FIGS. 3 and 4 is a melting device. This melting device 13 includes a melting tank 17 made of refractory materials such as graphite and quartz, wrought iron, and other materials to make a crucible, and a heating element 18 that is wound around the melting tank 17. It is arranged above the heat collection drum 10. The lower part of the melting tank 17 (the second is the axial direction of the heat collecting drum 10 (=
A nozzle 12 with an extending opening is provided, and the nozzle 1
A molten material 2 such as an aluminum alloy contained in the melting tank 17 flows out from the melting tank 17 in the form of a band, and the flow is continuously supplied to the outer circumferential surface of the heat collecting drum 10 . Reference numeral 19 denotes a communication pipe that communicates a gas supply source (not shown) with the melting tank 17, and the atmosphere or an inert gas such as argon is supplied from the gas supply source. 21 is a thermometer, and the molten material 2
Detects the temperature of

Next, the effect will be explained.

First, the molten material 2 is stored in the melting device 13.

For example, the molten material 2 melted in a melting furnace (not shown) is accommodated in the melting tank 17, and the molten material 2 is always maintained at a predetermined temperature by being heated by the heating element 184. The temperature is automatically controlled by a temperature control device (not shown), but the operator can visually check the temperature at that time using the thermometer 216. The atmosphere or argon gas having a constant pressure is supplied into the melting tank 17 via the melting tank 19, and the molten material 2 is applied with a predetermined pressure and flows out from the nozzle 12 in a band shape.

On the other hand, the heat collecting drum 10 is rotated at high speed by the operation of a rotating device 11 connected to the shaft 10 via a tortoise. The molten material 2 supplied to the rotating heat collecting drum 104 continuously contacts the outer peripheral surface of the heat collecting drum 10 in a band-like manner within a range slightly wider than the supply length of the molten material 2.

At this time, due to the rotation of the heat collecting drum 10, the molten material 2 is spread out in a plane on the upper surface of the heat collecting drum 10.

The molten material 2 spread out on the heat collecting drum 10 is cut by the step (-) between the outer peripheral surface portion 16 and the ring groove 15 in the axial direction, and the groove 4 is cut in the circumferential direction.
Difference in height of step 5 set by 4 = Therefore, cutting is performed. As a result, pieces of molten material, that is, pieces of foil 23 cut to a certain length L and width T, are adhered to a large number of facets 6 discontinuously formed by the steps 5. . Further, in each ring groove 15, four continuous filaments 3 are attached in the circumferential direction 1.

The width T of the foil piece 23 is the same as the thickness T of the drum large diameter section 7 and the drum small diameter section 8; Since t is determined by the circumferential speed of the heat collecting drum 10, the flow rate of the molten material 2, its viscosity, etc., these must be set in advance to desired dimensions and suitable manufacturing conditions.

The foil pieces 23 attached to each small surface 6 of the outer circumferential surface portion 16 of the heat collecting drum 10 and the filament 3 attached to the ring groove 15 are removed from the heat collecting drum 10 + two heats, and part or all of them are removed. As it solidifies, the centrifugal force accompanying the rotation of the heat collecting drum 10 causes each facet 6 and the link groove 15 to
They are separated from each other and scattered. Then, the foil piece 26 in flight is further cooled by the surrounding atmosphere and completely solidified, and in this way, a predetermined foil piece 23 is manufactured.

Therefore, as many foil pieces 23 as there are divided outer peripheral surfaces existing within the range to which the molten material 2 is supplied can be manufactured at once. Then, as described above, the foil piece 26
Since the production of the foil pieces 26 can be performed continuously, the production efficiency of the foil pieces 26 can be significantly increased.

In addition, the centrifugal force of the heat collecting drum 10 also causes scattering.
Even if some unused foil pieces 23 occur, the wiping action of the wiper 24 makes it possible to reliably remove such foil pieces 26 from each facet 6. The foil pieces 23 wiped off by the wiper 24 are stored and deposited in the box body 22 in the same way as the foil pieces 23 that have naturally scattered and peeled off. The manufacturing ratio of the foil pieces 23 can be increased as the width is narrower than the width T1.

Next, the results of experiments conducted based on this example will be shown.

material and dimensions of the heat collecting drum 16, experimental conditions C1 experimental results (11 In experiment 1, length L = 1.21, width T =
1.2 fins, 2 foil pieces 23 with a thickness of t-30 to 40 microns
4N was obtained. By the way, the diameter of molten material 2 is 0.5
The foil piece 23 obtained when feeding linearly (two times as M) is
It was 4%. In addition, the weight of 231 pieces of foil is 0.016
■It's about.

(2) The second experimental table has a length L = 1.1~1.3cm and a width T = 1.21111. Thirty-six pieces of foil-23 with a thickness t = 30-35 microns were obtained.

As is clear from these experimental results, according to the present invention, not only can foil pieces 23 with a small area be manufactured, but also a large number of foil pieces 26 can be manufactured at once. Since the nozzle 12 is wide, there is no fear that the nozzle 12 will become clogged, and it is possible to provide a foil piece manufacturing apparatus that is easy to handle and has few failures.

Note that the opening of the nozzle 12 has a length of 1 to 5 mm.
Approximately 0 ■ is suitable, but it may be longer than this,
In addition, the width is preferably about 0.1 inch to 511111 mm, but the width is the same as the size shown in this example (:
It is not limited. Moreover, the nozzle 12
The shape of the opening is not limited to a rectangular shape, but also one in which the gap at the middle part is narrower than the gap at both ends, and it is also possible to have a shape in which the molten material 2 is substantially formed in a band shape (which causes the molten material 2 to leak out). As the molten material 2, other than this embodiment, for example, alloys based on copper or nickel, iron, amorphous alloys, and various other materials can be used. In this case, it is necessary to set appropriate manufacturing conditions for each material.

9(A) and 9(B) show other embodiments of the shape of the bottom of the ring groove 15. That is, in FIG. 9(A), V
Figure 9 @) is a rectangular shape. Even if such a shape is used, the above embodiment (=
It can perform the same function as the ring groove in the case.

10 and 11 show a second embodiment of the invention.

In this embodiment, the small surface 6 of the outer circumferential surface portion 16 is
It is formed as an inclined plane that becomes higher from the front side toward the rear side in the 0th rotation i direction.

That is, V-shaped grooves 4 extending parallel to the axial direction of the heat collecting drum 10 are provided on the outer peripheral surface portion 16 at equal intervals (two or more) in the circumferential direction, and one side surface of the grooves 4 is used as a step 5. The other side is directly used as the facet 6.

Therefore, the outside of the step 5 intersects with one edge 9 of the facet 6, and the inside of the step directly intersects with the other edge of the facet 6.

The other configurations and operations are the same as those of the embodiment described above, and with this structure, the same effects as those of the embodiment described above can be obtained.

In addition, the heat collecting drum 10 is constructed by manufacturing the large diameter part forming the outer circumferential surface part 16 and the small diameter part forming the ring groove 15 separately and independently, and then assembling an appropriate number of these large and small parts alternately to form an integral structure. It is of course possible to do so.

As explained above (2. According to this invention (-), a heat collecting drum having a large number of facets is rotated at high speed, and molten material is continuously supplied from above in the form of a band to this heat collecting drum. By doing this, it is possible to directly manufacture foil pieces from the molten material.Moreover, within the range where the molten material is supplied (= one time for the number of outer circumference parts), it is not only possible to manufacture two foil pieces. This process for manufacturing foil pieces can be carried out continuously.

Furthermore, since the opening of the nozzle can be made large, there is no fear that the opening will become clogged. Furthermore, this invention (
According to 2, although it has a simple structure consisting of a heat collecting drum, a rotating device for rotating it at high speed, and a melting device for continuously supplying molten material to the heat collecting drum in the form of a belt, As described above, it is possible to provide a foil piece manufacturing apparatus with high production efficiency.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram showing an outline of a filament manufacturing apparatus as a prior art, and FIG. 2 is an enlarged cross-sectional view taken along the line ■-■ in FIG. Figure 3 is a front view showing the outline of the device, Figure 4 is a side view showing the outline of the equipment, Figure 5 is an enlarged perspective view of the main parts of the heat collecting drum, and Figure 6 is the heat collecting drum. Fig. 7 is a cross-sectional view taken along the line ■-■ of Fig. 6, Fig. 8 is a view showing the foil piece, Fig. 9
Figure (m) is a sectional view of the main part of a heat collecting drum showing a specific example of a pond with a ring groove shape, and Figure 9 @) is a sectional view of the main part of a heat collecting drum showing yet another specific example of a ring groove shape. 10 is an enlarged perspective view of the main part showing another example of the heat collection drum, and FIG.
The figure is an enlarged side view of the main parts of the heat collection drum. 2 is the molten material, 4 is the groove, 5 is the step, 6 is the facet, 9 is the edge, 1
0 is a heat collecting drum, 11 is a rotating device, 12 is a nozzle, 13
1 is a melting device, 15 is a ring groove, 16 is an outer peripheral surface portion, 17 is a melting tank, 18 is a heating element, 19 is a communicating pipe, 22 is a box body, 2
3 is a foil piece, 24 is a wiper 271

Claims (3)

[Claims] (1) In the circumferential direction (continuous ring grooves), the outer circumferential surface is divided into a plurality of parts in the axial direction, and each of the divided outer circumferential parts is discontinuously formed by steps. a heat collecting drum formed with a heat collecting drum, a rotating device for rotating the heat collecting drum at high speed, and a nozzle extending in the axial direction of the heat collecting drum; A foil piece manufacturing apparatus comprising: a melting device that continuously supplies the melted material to the outer peripheral surface of the heat collecting drum; (2) A patent characterized in that the step is formed by a groove extending parallel to the axial direction of the heat collecting drum, and the small surface is set in a portion excluding the groove, and the small surface forms a curved surface. A foil piece manufacturing apparatus according to claim 1. (3) The step is formed on one side of a V-shaped groove extending parallel to the axial direction of the heat collecting drum (2. The small surface is formed on the other side of this groove, and the small surface is formed on the other side of the groove. 2. The foil piece manufacturing apparatus according to claim 1, wherein the heating drum has an inclined plane that becomes higher from the front side toward the rear side in the rotational direction of the heat collecting drum.