Technical Field
[0001] The present invention relates to a spinning forming device configured to form a plate
in a desired shape while rotating the plate.
Background Art
[0002] Conventionally known is a spinning forming device configured to transform a plate
by pressing a processing tool against the plate while rotating the plate. The spinning
forming device normally includes a mandrel (shaping die) attached to a rotating shaft
and performs forming in such a manner that the plate is pressed against the mandrel
by the processing tool.
[0003] In recent years, proposed is a spinning forming device configured to perform spinning
forming while locally heating the plate. For example, as a spinning forming device
for a titanium alloy, PTL 1 discloses a spinning forming device configured such that
a portion of the plate which is pressed against the mandrel by a spatula (processing
tool) is heated by high frequency induction heating.
Citation List
Patent Literature
[0004] PTL 1: Japanese Laid-Open Patent Application Publication No.
2011-218427
Summary of Invention
Technical Problem
[0005] The inventors of the present invention have found that by locally heating the plate
by induction heating, the plate can be transformed into a final shape in the atmosphere
without using the mandrel. From this point of view, in an application (Japanese Patent
Application No.
2012-178269) preceding the present application, the applicant of the present application has
proposed a spinning forming device including, instead of the mandrel, a receiving
jig configured to support a central portion of the plate. According to this spinning
forming device, in the atmosphere away from the receiving jig, a transform target
portion of the plate is heated by a heater and is pressed by the processing tool.
To be specific, the plate is not pressed against the receiving jig by the processing
tool. In other words, unlike the mandrel, the receiving jig does not include a shaping
surface.
[0006] Generally, the receiving jig is smaller in size than the mandrel, and a heat capacity
thereof is small. Therefore, a part of the heat applied to the plate by the induction
heating is transferred through the receiving jig to the rotating shaft in a short
period of time. If a large amount of heat is transferred to the rotating shaft, the
rotating shaft may change in quality, or the durability of the rotating shaft may
deteriorate.
[0007] It is known from
EP 1728567 to provide a spinning forming device in which a blank is clamped at its circumference
and heated and shaped into a thin-walled bowl, by applying a vacuum to the convex
face and a shaping tool to the concave face.
[0008] An object of the present invention is to reduce the heat transferred from the plate
through the receiving jig to the rotating shaft in the spinning forming device.
Solution to Problem
[0009] The present invention provides, as a first aspect, a spinning forming device comprising:
a receiving jig for supporting a central portion of a plate to be formed, the plate
having an opening at a middle thereof; a rotating shaft to which the receiving jig
is attached; a heater configured to heat a transform target portion of the plate by
induction heating; and a processing tool configured to press the transform target
portion to transform the plate, wherein the receiving jig is configured to suppress
heat transfer from the plate to the rotating shaft; and wherein the receiving jig
includes a main body which has a disk shape and on which an edge portion of the plate
surrounding the opening is to be placed, and a tubular portion which projects from
the main body in an axial direction of the rotating shaft and is to be and is fitted
in the opening.
[0010] According to the above configuration, the heat transfer from the plate to the rotating
shaft is suppressed by the receiving jig itself. Therefore, the heat transfer from
the plate to the rotating shaft can be reduced. With this, the change in quality of
the rotating shaft and the deterioration of the durability of the rotating shaft can
be suppressed.
[0011] In the above configuration, the spinning forming device may further include: a fixing
jig sandwiching the plate together with the receiving jig; and a pressurizing rod
to which the fixing jig is attached and which presses the plate against the receiving
jig via the fixing jig, wherein the fixing jig is configured to suppress the heat
transfer from the plate to the pressurizing rod. According to this configuration,
the heat transferred from the plate through the fixing jig to the pressurizing rod
can be reduced, and the change in quality of the pressurizing rod and the deterioration
of the durability of the pressurizing rod can be suppressed.
[0012] For example, the fixing jig has any of the following configurations 1) to 3).
- 1) The fixing jig includes: a main body having a disk shape; and a heat insulator
disposed between the main body and the plate or between the main body and the pressurizing
rod.
- 2) The fixing jig includes: a main body having a disk shape; and a ring portion projecting
from a peripheral portion of the main body to contact the plate.
- 3) The fixing jig has a hollow structure whose internal space is filled with air or
a vacuum.
[0013] In the above configuration 2), a cross-sectional shape of the ring portion may be
pointed toward the plate, and through holes or grooves may be provided at the ring
portion so as to connect an inner peripheral surface of the ring portion and an outer
peripheral surface of the ring portion.
[0014] The present invention provides, as a second aspect, a spinning forming device comprising:
a receiving jig for supporting a central portion of a plate to be formed; a rotating
shaft to which the receiving jig is attached; a heater configured to heat a transform
target portion of the plate by induction heating; a processing tool configured to
press the transform target portion to transform the plate; wherein the receiving jig
is configured to suppress heat transfer from the plate to the rotating shaft; and
wherein the receiving jig includes: a main body having a disk shape; and a ring portion
projecting from a peripheral portion of the main body to contact the plate.
[0015] For example, the receiving jig has any of the following configurations A) or B).
- A) The receiving jig includes: a main body having a disk shape; and a heat insulator
disposed between the main body and the plate or between the main body and the rotating
shaft.
- B) The receiving jig has a hollow structure whose internal space is filled with air
or a vacuum.
[0016] In the above configuration B), a cross-sectional shape of the ring portion may be
pointed toward the plate, and through holes or grooves may be provided at the ring
portion so as to connect an inner peripheral surface of the ring portion and an outer
peripheral surface of the ring portion.
[0017] The present invention provides, as a third aspect, a spinning forming device including:
a receiving jig supporting a central portion of a plate to be formed; a rotating shaft
to which the receiving jig is attached; a heater configured to heat a transform target
portion of the plate by induction heating; a processing tool configured to press the
transform target portion to transform the plate; and a fixing jig sandwiching the
plate together with the receiving jig, wherein the fixing jig is constituted by a
peripheral wall and a ceiling wall so as to open toward the plate and is configured
such that air supplied by an air blowing means to an inside of the fixing jig through
an inlet provided at a center of the ceiling wall flows out through an outlet provided
at the peripheral wall.
[0018] According to the above configuration, the heat applied to the plate is radiated to
the air flowing through the inside of the fixing jig. Therefore, the heat transfer
from the plate through the receiving jig to the rotating shaft can be reduced. With
this, the change in quality of the rotating shaft and the deterioration of the durability
of the rotating shaft can be suppressed.
[0019] The spinning forming device may be configured such that the receiving jig is constituted
by a peripheral wall and a bottom wall so as to open toward the plate and is configured
such that the air supplied to the inside of the fixing jig is introduced to an inside
of the receiving jig through an opening provided at the plate and is discharged through
a discharge port provided at the peripheral wall. According to this configuration,
the heat is radiated from the receiving jig itself to the air flowing through the
inside of the receiving jig. Therefore, the heat transfer to the rotating shaft can
be further reduced.
[0020] The spinning forming device may be configured such that: a through hole is provided
at a region of the bottom wall of the receiving jig which overlaps the rotating shaft;
and an air passage through which the through hole communicates with a space around
the rotating shaft is formed at the rotating shaft. According to this configuration,
the rotating shaft can be further effectively protected from the heat.
[0021] The spinning forming device may be configured such that the heater is provided on
an opposite side of the processing tool across the plate. According to this configuration,
the heater can be located immediately close to the transform target portion of the
plate regardless of the shape of the plate during processing. With this, the transform
target portion can be appropriately heated.
Advantageous Effects of Invention
[0022] According to the present invention, the heat transferred from the plate through the
receiving jig to the rotating shaft can be reduced.
Brief Description of Drawings
[0023]
Fig. 1 is a schematic configuration diagram of a spinning forming device according
to Embodiment 1 of the present invention.
Fig. 2A is a plan view of a heater. Fig. 2B is a cross-sectional view taken along
line II-II of Fig. 2A.
Fig. 3 is a cross-sectional view of major portions of the spinning forming device
shown in Fig. 1.
Fig. 4 is a cross-sectional view of major portions of a spinning forming device according
to Embodiment 2 of the present invention.
Fig. 5 is a cross-sectional view of major portions of a spinning forming device according
to Embodiment 3 of the present invention.
Fig. 6 is a cross-sectional view of major portions of the spinning forming device
according to Modification Example 1 of Embodiment 3.
Fig. 7 is a cross-sectional view of major portions of the spinning forming device
according to Modification Example 2 of Embodiment 3.
Fig. 8A is a cross-sectional view of major portions of the spinning forming device
according to Modification Example 3 of Embodiment 3. Fig. 8B is a plan view of a receiving
jig.
Fig. 9 is a cross-sectional view of major portions of a spinning forming device according
to Embodiment 4 of the present invention.
Fig. 10 is a cross-sectional view of major portions of a spinning forming device according
to Embodiment 5 of the present invention.
Fig. 11 is a cross-sectional view of major portions of a spinning forming device according
to Embodiment 6 of the present invention.
Fig. 12 is a cross-sectional view of major portions of a spinning forming device according
to Embodiment 7 of the present invention.
Description of Embodiments
[0024] Hereinafter, embodiments of the present invention will be explained in reference
to the drawings.
Embodiment 1
[0025] Fig. 1 shows a spinning forming device 1A according to Embodiment 1 of the present
invention. The spinning forming device 1A includes a rotating shaft 2, a receiving
jig 3 attached to the rotating shaft 2, and a fixing jig 4. The receiving jig 3 supports
a central portion of a plate 9 to be formed, and the fixing jig 4 sandwiches the plate
9 together with the receiving jig 3. The spinning forming device 1A further includes:
a heater 6 configured to locally heat a transform target portion 91 of the plate 9
by induction heating, the transform target portion 91 being located away from a center
axis 20 of the rotating shaft 2 by a predetermined distance r; and a processing tool
7 configured to press the transform target portion 91 to transform the plate 9.
[0026] A direction (axial direction) in which the center axis 20 of the rotating shaft 2
extends is a vertical direction in the present embodiment. However, the axial direction
of the rotating shaft 2 may be a horizontal direction or an oblique direction. A lower
portion of the rotating shaft 2 is supported by a base 11. A motor (not shown) configured
to rotate the rotating shaft 2 is disposed in the base 11. An upper surface of the
rotating shaft 2 is flat, and the receiving jig 3 is fixed to the upper surface of
the rotating shaft 2.
[0027] The plate 9 is, for example, a flat circular plate. However, the shape of the plate
9 may be a polygonal shape or an oval shape. The plate 9 is not necessarily flat over
the entirety. For example, the central portion of the plate 9 may be thicker than
an outer peripheral portion of the plate 9, or the entire plate 9 or a part of the
plate 9 may be processed in advance to have a tapered shape. The material of the plate
9 is not especially limited and is, for example, a titanium alloy.
[0028] The receiving jig 3 has a size within a circle defined by a forming start position
of the plate 9. For example, in a case where the receiving jig 3 has a circular shape
in a plan view, a maximum diameter of the receiving jig 3 is equal to or smaller than
a diameter of the circle defined by the forming start position of the plate 9. Unlike
conventional shaping dies, the plate 9 is not transformed by being pressed against
a radially outer side surface of the receiving jig 3.
[0029] The fixing jig 4 is attached to a pressurizing rod 52. The pressurizing rod 52 is
driven by a driving portion 53 in an upper-lower direction to press the plate 9 against
the receiving jig 3 via the fixing jig 4. For example, the pressurizing rod 52 and
the driving portion 53 constitute a hydraulic cylinder. The driving portion 53 is
fixed to a frame 12 disposed above the rotating shaft 2, and a bearing rotatably supporting
the pressurizing rod 52 is incorporated in the driving portion 53.
[0030] The heater 6 and the processing tool 7 are respectively located at positions opposed
to each other across the center axis 20 of the rotating shaft 2. However, the heater
6 and the processing tool 7 are not necessarily located at such opposed positions.
In the present embodiment, the processing tool 7 is disposed at a front surface side
of the plate 9 (i.e., above the plate 9), and the heater 6 is disposed at a rear surface
side of the plate 9 (i.e., under the plate 9). In other words, the heater 9 is located
on the opposite side of the processing tool 7 across the plate 9. In a case where
the heater 6 is disposed on the opposite side of the processing tool 7 across the
plate 9 as above, the heater 6 can be located immediately close to the transform target
portion 91 of the plate 9 regardless of the shape of the plate 9 during processing.
With this, the transform target portion 91 can be appropriately heated. It should
be noted that the heater 6 may be disposed at the front surface side of the plate
9 so as to be located at the same side as the processing tool 7.
[0031] The heater 6 is moved by a first horizontal movement mechanism 15 in a radial direction
around the center axis 20 of the rotating shaft 2, and the first horizontal movement
mechanism 15 is moved in the vertical direction by a first vertical movement mechanism
16. Similarly, the processing tool 7 is moved by a second horizontal movement mechanism
13 in the radial direction around the center axis 20 of the rotating shaft 2, and
the second horizontal movement mechanism 13 is moved in the vertical direction by
a second vertical movement mechanism 14. Each of the first vertical movement mechanism
16 and the second vertical movement mechanism 14 extends so as to couple the base
11 and the frame 12.
[0032] In the present embodiment, used as the processing tool 7 is a roller configured to
follow the rotation of the plate 9 to rotate. However, the processing tool 7 is not
limited to the roller and may be a component including a spatula.
[0033] As shown in Figs. 2A and 2B, the heater 6 includes: a conducting wire 61 including
a coil portion 62 having a doubled circular-arc shape; and cores 65 configured to
collect magnetic force generated around the coil portion 62. The coil portion 62 includes
a pair of circular-arc portions spaced apart from each other in the radial direction
around the center axis 20 of the rotating shaft 2. The cores 65 are supported by a
supporting plate not shown. The frequency of an alternating current flowing through
the conducting wire 61 is not especially limited and is desirably a high frequency
of 5 to 400 kHz. To be specific, it is desirable that the induction heating by the
heater 6 be high frequency induction heating. According to the induction heating,
the temperature of a lower surface of the transform target portion 91 which is opposed
to the coil portion 62 becomes the highest by a skin effect. For example, in a case
where the material of the plate 9 is the titanium alloy, the temperature of the lower
surface of the transform target portion 91 is about 500 to 1,000°C.
[0034] Next, details of the receiving jig 3 and the fixing jig 4 will be explained in reference
to Fig. 3.
[0035] The receiving jig 3 is configured to suppress heat transfer from the plate 9 to the
rotating shaft 2. Specifically, the receiving jig 3 includes: a main body 31 having
a disk shape perpendicular to the center axis 20 of the rotating shaft 2 (see Fig.
1); and a heat insulator 32 disposed between the main body 31 and the plate 9. The
main body 31 is made of a metal. The heat insulator 32 may be an organic material
or an inorganic material. It is desirable that the heat insulator 32 have a certain
degree of stiffness such that the thickness thereof does not change even at the time
of the operation of the pressurizing rod 52. Examples of the heat insulator 32 include
low heat conductive materials, such as ceramics and the titanium alloy, and examples
of the ceramics include zirconia, alumina, and silicon nitride.
[0036] The fixing jig 4 is configured to suppress the heat transfer from the plate 9 to
the pressurizing rod 52. Specifically, the fixing jig 4 includes: a main body 41 having
a disk shape perpendicular to the center axis 20 of the rotating shaft 2; a heat insulator
42 disposed between the main body 41 and the plate 9; and a boss portion 40 interposed
between the main body 41 and the pressurizing rod 52 and having a smaller diameter
than the main body 41. The main body 41 is made of a metal. The heat insulator 42
may be an organic material or an inorganic material. As with the heat insulator 32
of the receiving jig 3, the heat insulator 42 of the fixing jig 4 may be an organic
material or an inorganic material. The material of the heat insulator 42 may be the
same as or different from the material of the heat insulator 32.
[0037] In the illustrated example, the diameter of the main body 41 of the fixing jig 4
is slightly smaller than the diameter of the main body 31 of the receiving jig 3.
However, the sizes of these diameters may be opposite to each other or may be the
same as each other.
[0038] As explained above, in the spinning forming device 1A of the present embodiment,
since the receiving jig 3 includes the heat insulator 32, the heat transfer from the
plate 9 to the rotating shaft 2 is suppressed by the receiving jig 3 itself. Therefore,
the heat transfer from the plate 9 to the rotating shaft 2 can be reduced, and the
change in quality of the rotating shaft 2 and the deterioration of the durability
of the rotating shaft 2 can be suppressed.
[0039] In the present embodiment, since the fixing jig 4 includes the heat insulator 42,
the heat transferred from the plate 9 through the fixing jig 4 to the pressurizing
rod 52 can be reduced, and the change in quality of the pressurizing rod 52 and the
deterioration of the durability of the pressurizing rod 52 can be suppressed.
Modification Example
[0040] In the above embodiment, the pressurizing rod 52 presses the plate 9 against the
receiving jig 3 via the fixing jig 4. However, the pressurizing rod 52 is not necessarily
required. For example, the fixing jig 4 may be fixed to the receiving jig 3 together
with the plate 9 by fastening members, such as bolts or clamps. In this case, the
fixing jig 4 may be constituted only by the main body 41. This modification is applicable
to the embodiments described below.
[0041] Further, in the above embodiment, the processing tool 7 is disposed above the plate
9, and the plate 9 is processed by the processing tool 7 so as to accommodate the
receiving jig 3, that is, open downward. However, the processing tool 7 may be disposed
under the plate 9, and the plate 9 may be processed by the processing tool 7 so as
to accommodate the fixing jig 4, that is, open upward. Or, to form a projection(s)
and a depression(s) on the plate 9, the position of the processing tool 7 may be changed
from the upper side of the plate 9 to the lower side of the plate or vice versa in
the middle of the processing of the plate 9.
Embodiment 2
[0042] Next, a spinning forming device 1B according to Embodiment 2 of the present invention
will be explained in reference to Fig. 4. In the present embodiment and Embodiments
3 to 7 described below, the same reference signs as Embodiment 1 are used for the
same components, and a repetition of the same explanation is avoided.
[0043] The spinning forming device 1B of the present embodiment is the same in configuration
as the spinning forming device 1A of Embodiment 1 except for the receiving jig 3 and
the fixing jig 4. In the present embodiment, the heat insulator 32 of the receiving
jig 3 is disposed between the main body 31 and the rotating shaft 2, not between the
main body 31 and the plate 9. Similarly, the heat insulator 42 of the fixing jig 4
is disposed between the boss portion 40 and the pressurizing rod 52, not between the
main body 41 and the plate 9.
[0044] The spinning forming device 1B configured as above can also have the same effects
as the spinning device 1A of Embodiment 1.
Embodiment 3
[0045] Next, a spinning forming device 1C according to Embodiment 2 of the present invention
will be explained in reference to Fig. 5. In the present embodiment, the receiving
jig 3 is also configured to suppress the heat transfer from the plate 9 to the rotating
shaft 2, and the fixing jig 4 is also configured to suppress the heat transfer from
the plate 9 to the pressurizing rod 52.
[0046] The receiving jig 3 includes: the main body 31 having the disk shape perpendicular
to the center axis 20 of the rotating shaft 2; and a ring portion 33 extending upward
from a peripheral portion of the main body 31 to contact the plate 9. In the present
embodiment, since the upper surface of the ring portion 33 is flat, the ring portion
33 surface-contacts the plate 9.
[0047] The fixing jig 4 includes: the main body 41 having the disk shape perpendicular to
the center axis 20 of the rotating shaft 2; a ring portion 43 extending downward from
a peripheral portion of the main body 41 to contact the plate 9; and the boss portion
40 interposed between the main body 41 and the pressurizing rod 52 and having a smaller
diameter than the main body 41. In the present embodiment, since a lower surface of
the ring portion 43 is flat, the ring portion 43 surface-contacts the plate 9.
[0048] The spinning forming device 1C configured as above can also have the same effects
as the spinning device 1A of Embodiment 1.
Modification Example
[0049] In the above embodiment, a cross-sectional shape of the ring portion 33 of the receiving
jig 3 is a rectangular shape. However, as shown in Fig. 6, the cross-sectional shape
of the ring portion 33 of the receiving jig 3 may be a triangular shape pointed upward
toward the plate 9. In this case, the ring portion 33 line-contacts the plate 9. This
configuration is especially useful in the case of bending the plate 9 at a position
where the ring portion 33 and the plate 9 contact each other. The triangular shape
that is the cross-sectional shape of the ring portion 33 may be a right angled triangle
as shown in Fig. 6 or an isosceles triangle inclining toward both sides from an apex
contacting the plate 9.
[0050] Similarly, although not shown, the cross-sectional shape of the ring portion 43 of
the fixing jig 4 may be a triangular shape pointed downward toward the plate 9.
[0051] As shown in Fig. 7, through holes 34 may be provided at the ring portion 33 of the
receiving jig 3 so as to connect an inner peripheral surface of the ring portion 33
and an outer peripheral surface of the ring portion 33. The heat transfer to the rotating
shaft 2 can be further reduced by the through holes 34.
[0052] Similarly, through holes 44 may be provided at the ring portion 43 of the fixing
jig 4 so as to connect an inner peripheral surface of the ring portion 43 and an outer
peripheral surface of the ring portion 43. The heat transfer to the pressurizing rod
52 can be further reduced by the through holes 44.
[0053] Or, as shown in Figs. 8A and 8B, instead of the through holes 34, grooves 35 may
be provided at the ring portion 33 of the receiving jig 3 so as to connect the inner
peripheral surface of the ring portion 33 and the outer peripheral surface of the
ring portion 33. Similarly, instead of the through holes 44, grooves 45 may be provided
at the ring portion 43 of the fixing jig 4 so as to connect the inner peripheral surface
of the ring portion 43 and the outer peripheral surface of the ring portion 43. The
depth of each groove (35, 45) may be equal to or less than the height of the ring
portion (33, 43).
[0054] In a case where the through holes (34, 44) or the grooves (35, 45) are provided at
the ring portion (33, 43), the cross-sectional shape of the ring portion may be a
triangular shape pointed toward the plate 9.
Embodiment 4
[0055] Next, a spinning forming device ID according to Embodiment 4 of the present invention
will be explained in reference to Fig. 9. In the present embodiment, the receiving
jig 3 is also configured to suppress the heat transfer from the plate 9 to the rotating
shaft 2, and the fixing jig 4 is also configured to suppress the heat transfer from
the plate 9 to the pressurizing rod 52.
[0056] Specifically, the receiving jig 3 is constituted only by the main body 31 having
a hollow structure, and the fixing jig 4 is constituted by the main body 41 having
a hollow structure and the boss portion 40. An internal space 37 of the main body
31 of the receiving jig 3 may be filled with air or may be a vacuum. Similarly, an
internal space 47 of the main body 41 of the fixing jig 4 may be filled with air or
may be a vacuum. To manufacture the main body whose internal space is a vacuum, a
sealed box may be formed by electron beam welding in a vacuum chamber.
[0057] The spinning forming device ID can also have the same effects as the spinning device
1A of Embodiment 1.
Embodiment 5
[0058] Next, a spinning forming device IE according to Embodiment 5 of the present invention
will be explained in reference to Fig. 10. In the present embodiment, the receiving
jig 3 is also configured to suppress the heat transfer from the plate 9 to the rotating
shaft 2. However, the fixing jig 4 is constituted only by: the main body 41 having
the disk shape perpendicular to the center axis 20 of the rotating shaft 2; and the
boss portion 40.
[0059] In the present embodiment, a circular opening 92 is provided at a middle of the plate
9. The receiving jig 3 includes: the main body 31 having the disk shape perpendicular
to the center axis 20 of the rotating shaft 2; and a circular tubular portion 30 located
at a middle of the main body 31 and projecting upward from the main body 31. An outer
diameter of the tubular portion 30 is set to be substantially equal to a diameter
of the opening 92. To be specific, an edge portion of the plate 9 which surrounds
the opening 92 is placed on the main body 31, and the tubular portion 30 is fitted
in the opening 92. A space inside the tubular portion 30 serves as a heat insulating
layer.
[0060] In the spinning forming device IE of the present embodiment, since the space inside
the tubular portion 30 serves as the heat insulating layer, the heat transfer from
the plate 9 to the rotating shaft 2 is suppressed by the receiving jig 3 itself. Therefore,
the heat transfer from the plate 9 to the rotating shaft 2 can be reduced, and the
change in quality of the rotating shaft 2 and the deterioration of the durability
of the rotating shaft 2 can be suppressed.
[0061] In the present embodiment, a contact area between the fixing jig 4 and the plate
9 is reduced by the opening 92 provided at the plate 9. Therefore, the heat transferred
from the plate 9 through the fixing jig 4 to the pressurizing rod 52 can be reduced,
and the change in quality of the pressurizing rod 52 and the deterioration of the
durability of the pressurizing rod 52 can be suppressed.
Embodiment 6
[0062] Next, a spinning forming device IF according to Embodiment 6 of the present invention
will be explained in reference to Fig. 11. In the present embodiment, the receiving
jig 3 is constituted only by the main body 31 having the disk shape perpendicular
to the center axis 20 of the rotating shaft 2.
[0063] The fixing jig 4 is constituted by a peripheral wall 48 and a ceiling wall 49 so
as to open toward the plate 9 (i.e., downward). In other words, the fixing jig 4 has
an inverted petri dish shape. A lower end surface of the peripheral wall 48 surface-contacts
the plate 9. An inlet 49a penetrating the ceiling wall 49 is provided at a center
of the ceiling wall 49, and outlets 48a penetrating the peripheral wall 48 are provided
at the peripheral wall 48. One end of an immovable air supply passage 8 is connected
to the inlet 49a so as to be rotatable relative to the fixing jig 4.
[0064] In the present embodiment, the pressurizing rod 52 (see Fig. 1) may or may not be
provided. In a case where the pressurizing rod 52 is provided, the air supply passage
8 is formed inside the pressurizing rod 52. In a case where the pressurizing rod 52
is not provided, the air supply passage 8 is constituted by a pipe.
[0065] An air blowing means not shown is connected to the other end of the air supply passage
8. A blower or the like can be used as the air blowing means. By the operation of
the air blowing means, the air is supplied through the air supply passage 8 and the
inlet 49a of the ceiling wall 49 to the inside of the fixing jig 4, and the air supplied
to the inside of the fixing jig 4 flows out through the outlets 48a of the peripheral
wall 48.
[0066] According to this configuration, the heat applied to the plate 9 is radiated to the
air flowing through the inside of the fixing jig 4. Therefore, the heat transfer from
the plate 9 through the receiving jig 3 to the rotating shaft 2 can be reduced. With
this, the change in quality of the rotating shaft 2 and the deterioration of the durability
of the rotating shaft 2 can be suppressed.
[0067] Instead of the blower connected to the other end of the air supply passage 8, for
example, an impeller which is disposed inside the fixing jig 4 and generates air flow
by the rotation of the fixing jig 4 may be used as the air blowing means. Or, both
the blower connected to the other end of the air supply passage 8 and the impeller
disposed inside the fixing jig 4 may be used as the air blowing means.
Embodiment 7
[0068] Next, a spinning forming device 1G according to Embodiment 7 of the present invention
will be explained in reference to Fig. 12. The spinning forming device 1G is obtained
by further improving the spinning forming device IF of Embodiment 6. To be specific,
the fixing jig 4 of the spinning forming device 1G is the same as the fixing jig 4
explained in Embodiment 6.
[0069] In the present embodiment, the circular opening 92 is provided at the middle of the
plate 9. The receiving jig 3 is constituted by a peripheral wall 38 and a bottom wall
39 so as to open toward the plate 9 (i.e., upward). In other words, the receiving
jig 3 has a petri dish shape. An upper end surface of the peripheral wall 38 surface-contacts
the plate 9. Discharge ports 38a penetrating the peripheral wall 38 are provided at
the peripheral wall 38. To be specific, the air supplied to the inside of the fixing
jig 4 is also introduced through the opening 92 of the plate 9 to the inside of the
receiving jig 3, and the air is then discharged through the discharge ports 38a of
the peripheral wall 38 to the outside.
[0070] According to this configuration, the heat is radiated from the receiving jig 3 itself
to the air flowing through the inside of the receiving jig 3. Therefore, the heat
transfer to the rotating shaft 2 can be further reduced.
[0071] Further, the present embodiment adopts a configuration for aggressively cooling down
the rotating shaft 2. Therefore, the rotating shaft 2 can be further effectively protected
from the heat.
[0072] Specifically, a through hole 39a is provided at a region of the bottom wall 39 of
the receiving jig 3 which overlaps the rotating shaft 2, and an air passage 23 through
which the through hole 39a communicates with a space around the rotating shaft 2 is
formed at the rotating shaft 2. Therefore, a part of the air flowing into the receiving
jig 3 is discharged through the through hole 39a and the air passage 23 to the space
around the rotating shaft 2. In the present embodiment, the through hole 39a is disposed
at a center of the bottom wall 39, and the air passage 23 is constituted by: a columnar
recession 21 provided at a center of the upper surface of the rotating shaft 2; and
lateral holes 22 extending laterally from the recession 21.
[0073] The configuration for cooling down the rotating shaft 2 is not limited to the structure
shown in Fig. 12. For example, the air passage 23 may be constituted by grooves formed
on the upper surface of the rotating shaft 2 to have a cross shape or a radial shape.
The through hole 39a provided at the bottom wall 39 is not necessarily disposed at
the center of the bottom wall 39, and through holes 39a may be provided on the same
circumference.
Other embodiments
[0074] The receiving jigs 3 and the fixing jigs 4 in Embodiments 1 to 5 may be combined
arbitrarily.
Reference Signs List
[0075]
- 1 A to 1G
- spinning forming device
- 2
- rotating shaft
- 23
- air passage
- 3
- receiving jig
- 30
- tubular portion
- 31
- main body
- 32
- heat insulator
- 33
- ring portion
- 34
- through hole
- 35
- groove
- 37
- internal space
- 38
- peripheral wall
- 38a
- discharge port
- 39
- bottom wall
- 39a
- through hole
- 4
- fixing jig
- 40
- boss
- 41
- main body
- 42
- heat insulator
- 43
- ring portion
- 44
- through hole
- 45
- groove
- 47
- internal space
- 48
- peripheral wall
- 48a
- outlet
- 49
- ceiling wall
- 49a
- inlet
- 52
- pressurizing rod
- 6
- heater
- 7
- processing tool
- 9
- plate
- 91
- transform target portion
- 92
- opening
1. A spinning forming device comprising:
a receiving jig (3) for supporting a central portion of a plate to be formed, the
plate having an opening (92) at a middle thereof;
a rotating shaft (2) to which the receiving jig is attached;
a heater (6) configured to heat a transform target portion (91) of the plate by induction
heating; and
a processing tool (7) configured to press the transform target portion to transform
the plate, wherein
the receiving jig is configured to suppress heat transfer from the plate to the rotating
shaft; and wherein
the receiving jig includes
a main body (31) which has a disk shape and on which an edge portion of the plate
surrounding the opening is to be placed, and
a tubular portion (30) which projects from the main body in an axial direction of
the rotating shaft and is to be fitted in the opening.
2. The spinning forming device according to claim 1, further comprising:
a fixing jig (4) for sandwiching the plate (9) together with the receiving jig (3);
and
a pressurizing rod (52) to which the fixing jig is attached and which presses the
plate against the receiving jig (3) via the fixing jig, wherein
the fixing jig is configured to suppress the heat transfer from the plate to the pressurizing
rod.
3. The spinning forming device according to claim 2, wherein the fixing jig (4) includes:
a main body (41) having a disk shape; and a heat insulator (42) which in use is disposed
between the main body and the plate (9) or is disposed between the main body and the
pressurizing rod (52).
4. The spinning forming device according to claim 2, wherein the fixing jig (4) includes:
a main body (41) having a disk shape; and a ring portion (43) projecting from a peripheral
portion of the main body for contacting the plate (9).
5. The spinning forming device according to claim 4, wherein a cross-sectional shape
of the ring portion (43) of the main body (41) of the fixing jig (4) is configured
to be pointed toward the plate (9).
6. The spinning forming device according to claim 4 or 5, wherein through holes (44)
or grooves (45) are provided at the ring portion (43) of the main body (41) of the
fixing jig (4) so as to connect an inner peripheral surface of the ring portion and
an outer peripheral surface of the ring portion.
7. The spinning forming device according to claim 2, wherein the fixing jig (4) has a
hollow structure whose internal space (47) is filled with air or a vacuum.
8. A spinning forming device comprising:
a receiving jig (3) for supporting a central portion of a plate (9) to be formed;
a rotating shaft (2) to which the receiving jig is attached;
a heater (6) configured to heat a transform target portion (91) of the plate by induction
heating;
a processing tool (7) configured to press the transform target portion to transform
the plate;
wherein the receiving jig is configured to suppress heat transfer from the plate to
the rotating shaft;
and wherein the receiving jig (3) includes: a main body (31) having a disk shape;
and a ring portion (33) projecting from a peripheral portion of the main body to contact
the plate.
9. The spinning forming device according to claim 8, wherein a cross-sectional shape
of the ring portion (33) is configured to be pointed toward the plate.
10. The spinning forming device according to claim 8 or 9, wherein through holes (34)
or grooves (35) are provided at the ring portion (33) so as to connect an inner peripheral
surface of the ring portion and an outer peripheral surface of the ring portion.
11. A spinning forming device comprising:
a receiving jig (3) for supporting a central portion of a plate (9) to be formed;
a rotating shaft (2) to which the receiving jig is attached;
a heater (6) configured to heat a transform target portion (91) of the plate by induction
heating;
a processing tool (7) configured to press the transform target portion to transform
the plate; and
a fixing jig (4) for sandwiching the plate together with the receiving jig, wherein
the fixing jig is constituted by a peripheral wall (48) and a ceiling wall (49) so
as to open toward the plate and is configured such that air supplied by an air blowing
means to an inside of the fixing jig through an inlet (49a) provided at a center of
the ceiling wall flows out through an outlet (48a) provided at the peripheral wall.
12. The spinning forming device according to claim 11, wherein:
the receiving jig (3) is constituted by a peripheral wall (38) and a bottom wall (39)
so as to open toward the plate (9) and is configured such that the air supplied to
the inside of the fixing jig is introduced to an inside of the receiving jig through
an opening (92) provided at the plate and is discharged through a discharge port (38a)
provided at the peripheral wall.
13. The spinning forming device according to claim 12, wherein:
a through hole (39a) is provided at a region of the bottom wall (39) of the receiving
jig (3) which overlaps the rotating shaft (2); and
an air passage (23) through which the through hole (39a) communicates with a space
around the rotating shaft is formed at the rotating shaft.
14. The spinning forming device according to any one of claims 1 to 13, wherein the heater
(6) is provided on an opposite side of the processing tool (7) across the plate (9).
1. Drückformvorrichtung umfassend:
eine Aufnahmeeinspannvorrichtung (3) zum Abstützen eines Mittelabschnitts einer zu
formenden Platte, wobei die Platte in ihrer Mitte eine Öffnung (92) aufweist;
eine Drehwelle (2), an der die Aufnahmeeinspannvorrichtung befestigt ist;
eine Heizvorrichtung (6), die dazu konfiguriert ist, einen Transformationszielabschnitt
(91) der Platte durch Induktionserwärmung zu erwärmen; und
ein Verarbeitungswerkzeug (7), das dazu konfiguriert ist, auf den Transformationszielabschnitt
zu drücken, um die Platte zu transformieren, wobei
die Aufnahmeeinspannvorrichtung dazu konfiguriert ist, die Wärmeübertragung von der
Platte auf die Drehwelle zu unterdrücken; und wobei
die Aufnahmeeinspannvorrichtung beinhaltet
einen Hauptkörper (31), der eine Scheibenform aufweist und auf dem ein die Öffnung
umgebender Randabschnitt der Platte zu platzieren ist, und
einen rohrförmigen Abschnitt (30), der in axialer Richtung der Drehwelle aus dem Hauptkörper
herausragt und in die Öffnung einzupassen ist.
2. Drückformvorrichtung nach Anspruch 1, weiter umfassend:
eine Fixiereinspannvorrichtung (4), um die Platte (9) zusammen mit der Aufnahmeeinspannvorrichtung
(3) sandwichartig zu verbinden; und
eine Druckstange (52), an der die Fixiereinspannvorrichtung befestigt ist und die
die Platte über die Fixiereinspannvorrichtung gegen die Aufnahmeeinspannvorrichtung
(3) drückt, wobei
die Fixiereinspannvorrichtung so konfiguriert ist, dass die Wärmeübertragung von der
Platte auf die Druckstange unterdrückt wird.
3. Drückformvorrichtung nach Anspruch 2, wobei die Fixiereinspannvorrichtung (4) umfasst:
einen Hauptkörper (41), der eine Scheibenform aufweist; und einen Wärmeisolator (42),
der im Gebrauch zwischen dem Hauptkörper und der Platte (9) oder zwischen dem Hauptkörper
und der Druckstange (52) angeordnet ist.
4. Drückformvorrichtung nach Anspruch 2, wobei die Fixiereinspannvorrichtung (4) beinhaltet:
einen Hauptkörper (41), der eine Scheibenform aufweist; und einen Ringabschnitt (43),
der von einem Umfangsabschnitt des Hauptkörpers vorsteht, um die Platte (9) zu berühren.
5. Drückformvorrichtung nach Anspruch 4, wobei eine Querschnittsform des Ringabschnitts
(43) des Hauptkörpers (41) der Fixiereinspannvorrichtung (4) so konfiguriert ist,
dass sie auf die Platte (9) gerichtet ist.
6. Drückformvorrichtung nach Anspruch 4 oder 5, wobei Durchgangslöcher (44) oder Nuten
(45) an dem Ringabschnitt (43) des Hauptkörpers (41) der Fixiereinspannvorrichtung
(4) vorgesehen sind, um eine innere Umfangsfläche des Ringabschnitts und eine äußere
Umfangsfläche des Ringabschnitts zu verbinden.
7. Drückformvorrichtung nach Anspruch 2, wobei die Fixiereinspannvorrichtung (4) eine
Hohlstruktur aufweist, deren Innenraum (47) mit Luft oder einem Vakuum gefüllt ist.
8. Drückformvorrichtung, umfassend:
eine Aufnahmeeinspannvorrichtung (3) zum Abstützen eines Mittelabschnitts einer zu
formenden Platte (9);
eine Drehwelle (2), an der die Aufnahmeeinspannvorrichtung befestigt ist;
eine Heizvorrichtung (6), die so konfiguriert ist, dass sie einen Transformationszielabschnitt
(91) der Platte durch Induktionserwärmung erwärmt;
ein Verarbeitungswerkzeug (7), das dazu konfiguriert ist, auf den Transformationszielabschnitt
zu drücken, um die Platte zu transformieren;
wobei die Aufnahmeeinspannvorrichtung dazu konfiguriert ist, die Wärmeübertragung
von der Platte auf die Drehwelle zu unterdrücken;
und wobei die Aufnahmeeinspannvorrichtung (3) beinhaltet: einen Hauptkörper (31),
der eine Scheibenform aufweist; und einen Ringabschnitt (33), der von einem Umfangsabschnitt
des Hauptkörpers vorsteht, um die Platte zu berühren.
9. Drückformvorrichtung nach Anspruch 8, wobei eine Querschnittsform des Ringabschnitts
(33) so konfiguriert ist, dass sie auf die Platte gerichtet ist.
10. Drückformvorrichtung nach Anspruch 8 oder 9, wobei Durchgangslöcher (34) oder Nuten
(35) an dem Ringabschnitt (33) vorgesehen sind, um eine innere Umfangsfläche des Ringabschnitts
und eine äußere Umfangsfläche des Ringabschnitts zu verbinden.
11. Drückformvorrichtung, umfassend:
eine Aufnahmeeinspannvorrichtung (3) zum Abstützen eines Mittelabschnitts einer zu
formenden Platte (9);
eine Drehwelle (2), an der die Aufnahmeeinspannvorrichtung befestigt ist;
eine Heizvorrichtung (6), die dazu konfiguriert ist, einen Transformationszielabschnitt
(91) der Platte durch Induktionserwärmung zu erwärmen;
ein Verarbeitungswerkzeug (7), das dazu konfiguriert ist, auf den Transformationszielabschnitt
zu drücken, um die Platte zu transformieren; und
eine Fixiereinspannvorrichtung (4) um die Platte zusammen mit der Aufnahmeeinspannvorrichtung
sandwichartig zu verbinden, wobei
die Fixiereinspannvorrichtung durch eine Umfangswand (48) und eine Deckenwand (49)
gebildet wird, so dass sie sich zu der Platte hin öffnet, und so konfiguriert ist,
dass Luft, die durch ein Luftblasmittel in das Innere der Fixiereinspannvorrichtung
durch einen in der Mitte der Deckenwand vorgesehenen Einlass (49a) zugeführt wird,
durch einen an der Umfangswand vorgesehenen Auslass (48a) ausströmt.
12. Drückformvorrichtung nach Anspruch 11, wobei:
die Aufnahmeeinspannvorrichtung (3) durch eine Umfangswand (38) und eine Bodenwand
(39) gebildet wird, so dass sie sich zu der Platte (9) hin öffnet, und so konfiguriert
ist, dass die in das Innere der Fixiereinspannvorrichtung zugeführte Luft durch eine
an der Platte vorgesehene Öffnung (92) in das Innere der Aufnahmeeinspannvorrichtung
eingeführt und durch eine an der Umfangswand vorgesehene Auslassöffnung (38a) abgeführt
wird.
13. Drückformvorrichtung nach Anspruch 12, wobei:
ein Durchgangsloch (39a) in einem Bereich der Bodenwand (39) der Aufnahmeeinspannvorrichtung
(3) vorgesehen ist, der die Drehwelle (2) überlappt; und
ein Luftdurchgang (23), durch den die Durchgangsbohrung (39a) mit einem Raum um die
Drehwelle herum in Verbindung steht, an der Drehwelle gebildet wird.
14. Drückformvorrichtung nach einem der Ansprüche 1 bis 13, wobei die Heizvorrichtung
(6) auf einer gegenüberliegenden Seite der Platte (9) von dem Verarbeitungswerkzeug
(7) vorgesehen ist.
1. Dispositif de formation par rotation comprenant :
un gabarit de réception (3) pour supporter une partie centrale d'une plaque à former,
la plaque présentant une ouverture (92) en son milieu ;
un arbre rotatif (2) auquel est attaché le gabarit de réception ;
un dispositif de chauffage (6) configuré pour chauffer une partie cible de transformation
(91) de la plaque par chauffage par induction ; et
un outil de traitement (7) configuré pour presser la partie cible de transformation
pour transformer la plaque, dans lequel
le gabarit de réception est configuré pour supprimer le transfert de chaleur depuis
la plaque vers l'arbre rotatif ; et dans lequel
le gabarit de réception inclut
un corps principal (31) qui présente une forme de disque et sur lequel une partie
bord de la plaque entourant l'ouverture doit être placée, et
une partie tubulaire (30) qui se projette depuis le corps principal dans une direction
axiale de l'arbre rotatif et doit être installée dans l'ouverture.
2. Dispositif de formation par rotation selon la revendication 1, comprenant en outre
:
un gabarit de fixation (4) pour prendre en sandwich la plaque (9) avec le gabarit
de réception (3) ; et
une tige de mise sous pression (52) à laquelle est attaché le gabarit de fixation
et qui presse la plaque contre le gabarit de réception (3) via le gabarit de fixation,
dans lequel
le gabarit de fixation est configuré pour supprimer le transfert de chaleur depuis
la plaque vers la tige de mise sous pression.
3. Dispositif de formation par rotation selon la revendication 2, dans lequel le gabarit
de fixation (4) inclut : un corps principal (41) présentant une forme de disque ;
et un isolant thermique (42) qui en utilisation est disposé entre le corps principal
et la plaque (9) ou est disposé entre le corps principal et la tige de mise sous pression
(52).
4. Dispositif de formation par rotation selon la revendication 2, dans lequel le gabarit
de fixation (4) inclut : un corps principal (41) présentant une forme de disque ;
et une partie bague (43) se projetant depuis une partie périphérique du corps principal
pour entrer en contact avec la plaque (9).
5. Dispositif de formation par rotation selon la revendication 4, dans lequel une forme
en coupe transversale de la partie anneau (43) du corps principal (41) du gabarit
de fixation (4) est configurée pour pointer vers la plaque (9).
6. Dispositif de formation par rotation selon la revendication 4 ou 5, dans lequel des
trous traversants (44) ou rainures (45) sont ménagés au niveau de la partie anneau
(43) du corps principal (41) du gabarit de fixation (4) de manière à relier une surface
périphérique intérieure de la partie anneau et une surface périphérique extérieure
de la partie anneau.
7. Dispositif de formation par rotation selon la revendication 2, dans lequel le gabarit
de fixation (4) présente une structure creuse dont l'espace interne (47) est rempli
d'air ou d'un vide.
8. Dispositif de formation par rotation comprenant :
un gabarit de réception (3) pour supporter une partie centrale d'une plaque (9) à
former ;
un arbre rotatif (2) auquel est attaché le gabarit de réception ;
un dispositif de chauffage (6) configuré pour chauffer une partie cible de transformation
(91) de la plaque par chauffage par induction ;
un outil de traitement (7) configuré pour presser la partie cible de transformation
pour transformer la plaque ;
dans lequel le gabarit de réception est configuré pour supprimer le transfert de chaleur
depuis la plaque vers l'arbre rotatif ;
et dans lequel le gabarit de réception (3) inclut : un corps principal (31) présentant
une forme de disque ; et une partie anneau (33) se projetant depuis une partie périphérique
du corps principal pour entrer en contact avec la plaque.
9. Dispositif de formation par rotation selon la revendication 8, dans lequel une forme
en coupe transversale de la partie anneau (33) est configurée pour pointer vers la
plaque.
10. Dispositif de formation par rotation selon la revendication 8 ou 9, dans lequel des
trous traversants (34) ou rainures (35) sont ménagés au niveau de la partie anneau
(33) de manière à relier une surface périphérique intérieure de la partie anneau et
une surface périphérique extérieure de la partie anneau.
11. Dispositif de formation par rotation comprenant :
un gabarit de réception (3) pour supporter une partie centrale d'une plaque (9) à
former ;
un arbre rotatif (2) auquel est attaché le gabarit de réception ;
un dispositif de chauffage (6) configuré pour chauffer une partie cible de transformation
(91) de la plaque par chauffage par induction ;
un outil de traitement (7) configuré pour presser la partie cible de transformation
pour transformer la plaque ; et
un gabarit de fixation (4) pour prendre en sandwich la plaque avec le gabarit de réception,
dans lequel
le gabarit de fixation est constitué par une paroi périphérique (48) et une paroi
de plafond (49) de manière à s'ouvrir vers la plaque et est configuré de telle sorte
que de l'air apporté par un moyen de soufflage d'air vers un intérieur du gabarit
de fixation à travers une entrée (49a) ménagée au niveau d'un centre de la paroi de
plafond s'écoule à l'extérieur à travers une sortie (48a) ménagée au niveau de la
paroi périphérique.
12. Dispositif de formation par rotation selon la revendication 11, dans lequel :
le gabarit de réception (3) est constitué par une paroi périphérique (38) et une paroi
de fond (39) de manière à s'ouvrir vers la plaque (9) et est configuré de telle sorte
que l'air apporté à l'intérieur du gabarit de fixation est introduit dans un intérieur
du gabarit de réception à travers une ouverture (92) ménagée au niveau de la plaque
et est évacué à travers un orifice d'évacuation (38a) ménagé au niveau de la paroi
périphérique.
13. Dispositif de formation par rotation selon la revendication 12, dans lequel :
un trou traversant (39a) est ménagé au niveau d'une région de la paroi de fond (39)
du gabarit de réception (3) qui chevauche l'arbre rotatif (2) ; et
un passage d'air (23) à travers lequel le trou traversant (39a) communique avec un
espace autour de l'arbre rotatif est formé au niveau de l'arbre rotatif.
14. Dispositif de formation par rotation selon l'une quelconque des revendications 1 à
13, dans lequel le dispositif de chauffage (6) est ménagé sur un côté opposé de l'outil
de traitement (7) d'un bout à l'autre de la plaque (9).