U.S. patent application number 11/326323 was filed with the patent office on 2006-06-01 for ball given quantity supply apparatus and method and apparatus for assembling ball screw apparatus.
This patent application is currently assigned to NSK LTD.. Invention is credited to Hiroshi Araki, Kazuyasu Chiba.
Application Number | 20060112561 11/326323 |
Document ID | / |
Family ID | 32072455 |
Filed Date | 2006-06-01 |
United States Patent
Application |
20060112561 |
Kind Code |
A1 |
Chiba; Kazuyasu ; et
al. |
June 1, 2006 |
Ball given quantity supply apparatus and method and apparatus for
assembling ball screw apparatus
Abstract
There are provided with a ball given quantity supply apparatus
for supplying a given quantity of balls to an apparatus using a
given quantity of balls such as a bearing, a ball screw and a
linear guide, and a method and apparatus for assembling a ball
screw apparatus for use in a feed mechanism employed in various
machines.
Inventors: |
Chiba; Kazuyasu; (Kanagawa,
JP) ; Araki; Hiroshi; (Kanagawa, JP) |
Correspondence
Address: |
SUGHRUE MION, PLLC
2100 PENNSYLVANIA AVENUE, N.W.
SUITE 800
WASHINGTON
DC
20037
US
|
Assignee: |
NSK LTD.
|
Family ID: |
32072455 |
Appl. No.: |
11/326323 |
Filed: |
January 6, 2006 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
10665182 |
Sep 22, 2003 |
|
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|
11326323 |
Jan 6, 2006 |
|
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Current U.S.
Class: |
29/898.04 ;
29/434; 29/456 |
Current CPC
Class: |
Y10T 29/49998 20150115;
B65G 47/1478 20130101; F16C 43/06 20130101; B23P 19/001 20130101;
Y10T 29/49881 20150115; Y10T 29/53478 20150115; Y10T 29/49643
20150115; Y10T 29/53104 20150115; B23P 19/004 20130101; Y10T
29/4984 20150115; Y10T 29/49948 20150115 |
Class at
Publication: |
029/898.04 ;
029/434; 029/456 |
International
Class: |
B23P 11/00 20060101
B23P011/00; B21D 39/00 20060101 B21D039/00 |
Foreign Application Data
Date |
Code |
Application Number |
Sep 26, 2002 |
JP |
P. 2002-280250 |
Apr 24, 2003 |
JP |
P. 2003-120154 |
Claims
1. A method for assembling a ball screw apparatus, comprising the
steps of: loosely fitting a nut with a circulating part previously
assembled thereto with a provisional shaft including a tapered step
portion formed between a small-diameter shaft portion and a
large-diameter shaft portion thereof; in this state, fitting a ball
insertion jig into between the provisional shaft and the nut from
the small-diameter shaft portion and rotating the provisional shaft
to introduce a given number of balls inserted from the ball passage
of the ball insertion jig into between the screw groove of the nut
and the provisional shaft through a guide portion formed between
the ball insertion jig and the tapered step portion; moving the
provisional shaft to the small-diameter shaft portion side with
respect to the nut and the ball insertion jig to allow the balls
existing in the guide portion to climb over the tapered step
portion, introducing the balls into between the screw groove of the
nut and the provisional shaft; and fitting the screw shaft of the
ball screw apparatus with the nut.
2. The method for assembling a ball screw apparatus as set forth in
claim 1, wherein when introducing the balls into between the screw
groove of the nut and the provisional shaft, the nut is made
eccentric to the provisional shaft.
3. An apparatus for assembling a ball screw apparatus, comprising:
a provisional shaft which includes a tapered step portion formed
between a small-diameter shaft portion and a large-diameter shaft
portion thereof and also with which a nut of the ball screw
apparatus with a circulating part previously assembled thereto can
be loosely fitted; a drive device for rotating the provisional
shaft; a ball insertion jig fittable into between the provisional
shaft and the nut from the small-diameter shaft portion, including
a ball passage for receiving a given number of balls, defining a
guide portion between the tapered step portion and itself, and
capable of introducing the balls inserted into the ball passage
into between the provisional shaft and a screw groove formed in the
nut, and a moving device the provisional shaft to the
small-diameter shaft portion side with respect to the nut and the
ball insertion jig.
4. The apparatus for assembling a ball screw apparatus as set forth
in claim 3, wherein the ball insertion jig includes: a ball stopper
disposed on the ball exit side of the ball passage so as to
separate the ball exit portion or ball entrance portion of the
circulating part from the guide portion in order to be able to
prevent the balls introduced into between the screw groove of the
nut and the provisional shaft from interfering with the balls
inserted from the ball passage; and a projection for preventing the
balls inserted from the ball passage from touching directly the
groove shoulder of the screw groove of the nut, said projection
being disposed on the leading end portion of the ball stopper.
5. The apparatus for assembling a ball screw apparatus as set forth
in claim 3, wherein an elastic member is applied to, buried in,
shrinkage fitted with, or bonded to the outer peripheral surface of
the provisional shaft including the tapered step portion.
Description
[0001] This is a divisional of application Ser. No. 10/665,182
filed Sep. 22, 2003, the entire disclosure of the prior
application, application Ser. No. 10/665,182 is hereby incorporated
by reference.
BACKGROUND OF THE INVENTION
[0002] The present invention relates to a ball given quantity
supply apparatus for supplying a given quantity of balls to an
apparatus using a given quantity of balls such as a bearing, a ball
screw and a linear guide.
[0003] Further, the present invention relates to method and
apparatus for assembling a ball screw apparatus for use in a feed
mechanism employed in various machines.
[0004] A ball given quantity supply apparatus of this type is
widely known because it is disclosed, for example, in the Examined
Japanese Utility Model Application Publication No. Heil-24025 and
the Japanese Patent No. 2991412.
[0005] A ball given number take-out apparatus (ball given number
supply apparatus) disclosed in the Examined Japanese Utility Model
Application Publication No. Heil-24025 comprises: a hopper 1 in
which a plurality of balls W can be stored; a cylindrical-shaped
fixed guide 2 fixed to the lower surface of the hopper 1 and
extended downwardly therefrom; a collecting tube 4 supported in an
internal hole formed in the fixed guide 2 in such a manner that it
can be slided in a given range in the upward and downward
directions, the collecting tube 4 including a ball passage 3 formed
so as to penetrate there through in the upward and downward
directions; a inducing tube 5 fixed to the upper end portion of the
ball passage 3, penetrating through the bottom wall of the hopper 1
so as to be slidable in the upward and downward directions, and
projected to the downwardly inclined inner bottom surface of the
hopper 1; and, shutter members 6, 7 respectively disposed in the
two upper and lower portions of the collecting tube 4, while each
of them is able to project and retreat between a projecting
position in which it projects into the ball passage 3 to thereby
close the ball passage 3 and a retreating position in which it
retreats from the ball passage 3 to thereby open the ball passage
3. The shutter members 6, 7 are respectively energized toward their
associated retreating positions by their associated spring members
10; however, due to the action of a cam portion 8 disposed on the
inner peripheral surface of the fixed guide 2, while the collecting
tube 4 is being positioned at the lower end position of the
above-mentioned given range in the internal hole of the fixed guide
2, the upper shutter member 6 is disposed at the retreating
position and the lower shutter member 7 is disposed at the
projecting position. Also, while the collecting tube 4 is being
positioned at the upper end position of the above-mentioned given
range in the internal hole of the fixed guide 2, the upper shutter
member 6 is disposed at the projecting position and the lower
shutter member 7 is disposed at the retreating position.
[0006] While the collecting tube 4 is being disposed at the above
lower end position, the lower end portion of the collecting pipe 4
is projected downwardly from the lower end of the internal hole of
the fixed guide 2 and the plurality of balls W moved from the inner
bottom surface of the hopper 1 into the inducing pipe 5 reach the
lower shutter member 7 disposed at the projecting position in the
ball passage 3.
[0007] And, in case where the lower end portion of the collecting
tube 4 at the above-mentioned upper lower end position is pushed
upwardly to thereby move the collecting tube 4 up to the
above-mentioned upper end position, due to the action of the cam
portion 8 of the inner peripheral surface of the fixed guide 2, the
lower shutter member 7 is moved to the retreating position and the
upper shutter member 6 is moved to the projecting position, so that
a given number of balls W in the range of the ball passage 3
between the lower shutter member 7 and upper shutter member 6 are
discharged from the end wall of the ball passage 3.
[0008] Further, in case where the push-up operation of the lower
end portion of the collecting tube 4 at the above upper end
position is stopped to thereby move the collecting tube 4 to the
above lower end position, due to the action of the cam portion 8 of
the inner peripheral surface of the fixed guide 2, the lower
shutter member 7 is moved to the projecting position and also the
upper shutter member 6 is moved to the retreating position, so that
a plurality of balls W moved into the inducing tube 5 are allowed
to reach again the lower shutter member 7 at the projecting
position in the ball passage 3 of the collecting tube 4.
[0009] Now, a ball given quantity supply apparatus disclosed in the
Japanese Patent No. 2991412 comprises: a ball storage case 21 in
which a plurality of balls 23 are stored; an air blow-in portion 22
for blowing the air into the ball storage case 21; a ball supply
tube 24 to which the balls 23 are supplied from within the ball
storage case 21 by the air blown from the air blow-in portion 22
into the ball storage case 21; and, a rotation block 7 which is
disposed on the leading end of the ball supply tube 24 and also
which includes a ball storage portion 7a formed so as to penetrate
through the rotation block 7 for storing a given number of balls 23
therein. The rotation block 7 is held by and between an upper plate
5 and a lower plate 6. In the upper plate 5, the leading end of the
ball supply tube 24 is fixed to a given position on the rotation
locus of the upper end of the ball storage portion 7a of the
rotation block 7. Also, in the lower plate 6, there is formed a
ball discharge hole 6a at a given position on the rotation locus of
the lower end of the ball storage portion 7a of the rotation block
7. By the way, the leading end of the ball supply tube 24 at the
above given position of the upper plate 5 and the ball discharge
hole 6a at the above given position of the lower plate 6 are
disposed with the ball storage portion 7a of the rotation block 7
between them, but they are not on a straight line in the vertical
direction.
[0010] And, while the upper end of the ball storage portion 7a of
the rotation block 7 and the leading end of the ball supply tube 24
of the upper plate 5 are disposed on a straight line in the
vertical direction, a plurality of balls 23 are supplied from the
ball supply tube 24 into the ball storage portion 7a. Next, while
the rotation block 7 is rotated so that the upper end of the ball
storage portion 7a of the rotation block 7 is shut off from the
leading end of the ball supply tube 24 of the upper plate 5 and
further the lower end of the ball storage portion 7a and the ball
discharge hole 6a of the lower plate 6 are disposed on a straight
line in the vertical direction, a given number of balls 23 stored
within the ball storage portion 7a are discharged from the ball
discharge hole 6a.
[Patent Literature 1]
[0011] The Examined Japanese Utility Model Application Publication
No. Hei1-24025 (FIGS. 1 to 3) [Patent Literature 2] [0012] The
Japanese Patent No. 2991412 (FIGS. 2 and 3)
[0013] In the ball given number take-out apparatus (ball given
quantity supply apparatus) disclosed in the Examined Japanese
Patent Utility Model No. Hei1-24025 and structured and operated in
the above-mentioned manner, each time there arises the need to
discharge a given quantity of balls W, the collecting tube 4 must
be slided by a given distance in the vertical direction within the
internal hole of the fixed guide 2; however, this sliding motion of
the collecting tube 4 makes it difficult for the given quantity of
balls W to be discharged quickly.
[0014] Also, in the above ball given quantity take-out apparatus
(ball given quantity supply apparatus), each time the collecting
tube 4 is slided by a given distance in the vertical direction
within the internal hole of the fixed guide 2, the upper end
portion of the inducing tube 5 is slided in the vertical direction
with respect to the bottom wall of the hopper 1 to thereby allow a
plurality of balls W stored in the hopper 1 to flow into the
inducing tube 5. However, in this case, there is a possibility that
the plurality of balls W in the hopper 1 can concentrate toward the
opening of the upper end of the inducing tube 5 and thus can be
clogged there. And, such clogging makes it difficult for a given
quantity of balls W to be discharged positively. Further, a ball to
be supplied to a bearing, a ball screw and a linear guide, in many
cases, is covered with oil which has a relatively high coefficient
of viscosity, for example, anticorrosive oil; and, in case where
such ball is used in the above ball given number take-out apparatus
(ball given quantity supply apparatus), the above-mentioned
clogging phenomenon is easier to occur.
[0015] Further, since the above ball given number take-out
apparatus (ball given quantity supply apparatus) does not include
device for detecting that a given number of balls are held in the
range between the upper and lower shutter members 6 and 7 in the
ball passage 3 of the collecting tube 4 while the collecting tube 4
is disposed at the above lower end position, there is a possibility
that, although the above-mentioned clogging phenomenon occurs and
thus a given number of balls W are not held in the above range, the
collecting tube 4 can be slided from the above lower end position
to the above upper end position and thus a given number of balls W
cannot be discharged from the lower end of the ball passage 3.
[0016] In the ball given quantity supply apparatus disclosed in the
Japanese Patent No. 2991412, which is structured in the
above-mentioned manner and can operate in the above-mentioned
manner, supply of the balls 23 from the ball storage case 21 to the
ball supply tube 24 by the air blown from the air blow-in portion
22 into the ball storage case 21 becomes unstable in case where the
number of balls 23 stored in the ball storage case 21 is small.
Also, in case where balls often covered with oil having a
relatively high coefficient of viscosity so as to be supplied to a
bearing, a ball screw and a linear guide are stored in the ball
storage case 21, the above-mentioned supply of the balls from the
ball storage case 21 into the ball supply tube 24 by the air blown
into the ball storage case 21 from the air blow-in portion 22 can
be unstable.
[0017] Therefore, in case where the number of balls 23 stored in
the ball storage case 21 is small, or in case where balls covered
with oil having a relatively high coefficient of viscosity, for
example, anticorrosive oil, are stored in the ball storage case 21
in a large number, there is a possibility that the number of balls
23 stored in the ball supply tube 24 can be smaller than the given
number of the balls 23 that can be stored into the ball storage
portion 7a of the rotation block 7. Due to this, there is a fear
that the number of the balls 23 to be discharged through the ball
discharge hole 6a of the lower plate 6 from the ball storage
portion 7a of the rotation block 7 can be smaller than the above
given number.
[0018] Further, a ball screw apparatus comprises: a screw shaft and
a nut loosely fitted with the screw shaft; the screw shaft includes
a spiral-shaped screw groove formed in the outer peripheral surface
thereof and extends in the axial direction thereof, and the nut
includes a spiral-shaped screw groove corresponding to the
spiral-shaped screw groove of the screw shaft; and, the screw
groove of the nut and the screw groove of the screw shaft are
disposed opposed to each other to thereby form a load passage
between the two grooves. A large number of balls serving as rolling
bodies are rollably held in the load passage and, to the nut, there
is assembled a circulating part such as a circulating tube which
allows the balls rolling along the load passage to circulate
endlessly. And, in case where the screw shaft (or the nut) is
rotated, the nut (or the screw shaft) can be moved in the axial
direction through the rolling movements of the balls.
[0019] By the way, as a method for assembling the ball screw
apparatus of the above type, for example, there is known a method
(for example, see patent literature 3 and patent literature 4), in
which, with a nut loosely fitted with a screw shaft having a
horizontally disposed axial line, a given number of balls inserted
into the nut from a ball insertion hole formed in the nut to
thereby introduce the balls into a load passage formed between the
nut and screw shaft, and, next, the ball insertion hole is closed
by a circulating part such as a circulating tube holding the given
number of balls therein.
[0020] However, in the above method, since the circulating part
holding the given number of balls is used to close the ball
insertion hole, there is a fear that the balls can fly out from the
circulating part and thus the given number of balls cannot be
inserted into the nut, that is, there is found a problem in the
respect of the operation efficiency.
[0021] Thus, as a method which can solve the above problem, for
example, there is proposed the following method for assembling a
ball screw apparatus (for example, see patent literature 5).
[0022] That is, according to the assembling method disclosed in the
patent literature 5, a nut, to which a circulating part is
previously assembled, is loosely fitted with a provisional shaft
having a vertically disposed axial line; after the phase of the
ball exit of a ball introduction passage opened up in the interior
of the provisional shaft is matched to the highest position of the
screw groove of the nut, a given number of balls are passed into
the ball introduction passage at the same time to thereby introduce
the balls into between the screw groove of the nut and provisional
shaft; next, the balls which could not be introduced into between
the screw groove and provisional shaft and are left within the ball
introduction passage, are pushed into between the screw groove and
provisional shaft using a ball push-in rod; and, after completion
of the ball insertion operation, the provisional shaft and screw
shaft are engaged with each other, and the nut and screw shaft are
fitted with each other at the same time when the provisional shaft
is removed from the screw shaft.
[Patent Literature 3]
[0023] The Examined Japanese Patent Application Publication No.
Sho62-22737 [Patent Literature 4] [0024] The Examined Japanese
Utility Model Application Publication No. Hei6-50108 [Patent
Literature 5] [0025] The Japanese Patent No. 2530401
[0026] However, in the ball screw apparatus assembling method
disclosed in the patent literature 5, since the balls, which could
not be introduced into between the screw groove of the nut and
provisional shaft are left in the ball introduction passage, are
pushed into between them using the ball push-in rod, there is a
fear that the smaller the lead of the screw groove of the nut is,
the more easily the balls can be clogged, which-makes it difficult
to introduce the balls into the nut smoothly.
SUMMARY OF THE INVENTION
[0027] The present invention aims at eliminating the above
drawbacks found in the above-cited conventional ball given quantity
supply apparatus. Accordingly, it is an object of the invention to
provide a ball given quantity supply apparatus which, even in case
where balls often covered with oil having a relatively high
coefficient of viscosity such as anticorrosive oil for supply to a
bearing, a ball screw and a linear guide are supplied in a given
quantity, is always able to supply a given quantity of balls
positively and quickly.
[0028] In attaining the above object, according to the invention,
there is provided a ball given quantity supply apparatus,
comprising: a ball storage portion for storing a plurality of balls
therein; ball arranging device for arranging a plurality of balls
stored in the ball storage portion in a line; ball delivery device
including a ball passage extended from the ball storage portion so
as not only to be able to receive a plurality of balls arranged in
a line by the ball arranging device but also to allow the plurality
of balls in a line supplied thereto to pass therethrough, the ball
delivery device being capable of delivering the plurality of balls
arranged in a line in the ball passage from the ball storage
portion to the extended end portion of the ball passage using
gravity; first gate device disposed at a position near to the ball
storage portion in the ball passage of the ball delivery device for
opening and closing the ball passage; second gate device disposed
at position more distant from the ball storage portion in the ball
passage of the ball delivery device than the first gate device for
opening and closing the ball passage and also for holding a given
quantity of balls between the first gate device and itself;
pressurized fluid jetting device disposed in the vicinity of the
first gate device in the ball passage of the ball delivery device
for jetting out a pressurized fluid onto the balls to thereby
separate substances attached to the surfaces of the balls from
these surfaces; and, operation control device for detecting that a
given quantity of balls are held between the first and second gate
device in the ball passage of the ball delivery device, and also
for controlling the operations of the first and second gate
device.
[0029] And, the operation control device opens the first gate
device and closes the second gate device while the plurality of
balls arranged in a line by the ball arranging device are being
supplied into the ball passage of the ball delivery device, and
also closes the first gate device and opens the second gate device
after it detects that a given quantity of balls are held between
the first and second gate device in the ball passage of the ball
delivery device.
[0030] Now, description will be given below in detail of an
embodiment of a ball given quantity supply apparatus according to
the invention with reference to the accompanying drawings.
[0031] Further, the present invention aims at eliminating the above
drawback found in the above-cited conventional ball screw apparatus
assembling method. Accordingly, it is an object of the invention to
provide method and apparatus for assembling a ball screw apparatus
which can assemble a given number of balls into a nut smoothly.
[0032] In attaining the above object, according to the invention as
set forth Aspect 15, there is provided a method for assembling a
ball screw apparatus, comprising the steps of: loosely fitting a
nut with a circulating part previously assembled thereto with a
provisional shaft including a tapered step portion formed between a
small-diameter shaft portion and a large-diameter shaft portion
thereof; in this state, fitting a ball insertion jig into between
the provisional shaft and the nut from the small-diameter shaft
portion and rotating the provisional shaft to thereby introduce a
given number of balls inserted from, the ball passage of the ball
insertion jig into between the screw groove of the nut and the
provisional shaft through a guide portion formed between the ball
insertion jig and the tapered step portion; then, moving the
provisional shaft to the small-diameter shaft portion side with
respect to the nut and the ball insertion jig to allow the balls
existing in the guide portion to climb over the tapered step
portion, thereby introducing the balls into between the screw
groove of the nut and the provisional shaft; and then, fitting the
screw shaft of the ball screw apparatus with the nut.
[0033] According to a method for assembling a ball screw apparatus
as set forth in Aspect 16, in a method for assembling a ball screw
apparatus as set forth in Aspect 15, when introducing the balls
into between the screw groove of the nut and the provisional shaft,
the nut is made eccentric to the provisional shaft.
[0034] And, according to the invention as set forth in Aspect 17,
there is provided an apparatus for assembling a ball screw
apparatus, comprising: a provisional shaft which includes a tapered
step portion formed between a small-diameter shaft portion and a
large-diameter shaft portion thereof and also with which a nut of
the ball screw apparatus with a circulating part previously
assembled thereto can be loosely fitted; drive device for rotating
the provisional shaft; a ball insertion jig fittable into between
the provisional shaft and the nut from the small-diameter shaft
portion, including a ball passage for receiving a given number of
balls, defining a guide portion between the tapered step portion
and itself, and capable of introducing the balls inserted into the
ball passage into between the provisional shaft and a screw groove
formed in the nut and; moving device for moving the provisional
shaft to the small-diameter shaft portion side with respect to the
nut and the ball insertion jig.
[0035] According to the invention as set forth in Aspect 18, in an
apparatus for assembling a ball screw apparatus as set forth in
Aspect 17, the ball insertion jig includes a ball stopper disposed
on the ball exit side of the ball passage so as to separate the
ball exit portion or ball entrance portion of the circulating part
from the guide portion in order to be able to prevent the balls
introduced into between the screw groove of the nut and the
provisional shaft from interfering with the balls inserted from the
ball passage; and, on the leading end portion of the ball stopper,
there is disposed a projection for preventing the balls inserted
from the ball passage from touching directly the groove shoulder of
the screw groove of the nut.
[0036] According the invention as set forth in Aspect 19, in an
apparatus for assembling a ball screw apparatus as set forth in
Aspect 17 or 18, an elastic member is applied to, buried in,
shrinkage fitted with, or bonded to the outer peripheral surface of
the provisional shaft including the tapered step portion.
BRIEF DESCRIPTION OF THE DRAWINGS
[0037] FIG. 1 is a schematically perspective view of the whole of a
ball given quantity supply apparatus according to an embodiment of
the invention;
[0038] FIG. 2A is a schematically longitudinal section view of a
ball storage portion, taken along the line II(A)-II(A) shown in
FIG. 1; and, FIG. 2B is a schematically transverse section view of
the ball storage portion, taken along the line II(B)-II(B) shown in
FIG. 1;
[0039] FIG. 3 is a schematically transverse section view taken
along the line III-III shown in FIG. 1;
[0040] FIG. 4A is a schematically horizontal section view of the
base end portion of ball delivery device which is disposed in the
vicinity of the ball storage portion and in which first gate device
and pressurized fluid jetting device are disposed, and the portion
of the ball storage portion that adjoins the base end portion of
the ball delivery device; and, FIG. 4B is a schematically
longitudinal section view of the above base end portion of the ball
delivery device and the portion of the ball storage portion
adjoining the present base end portion;
[0041] FIG. 5A is a schematically horizontal section view of the
extended end portion of the ball delivery device which is distant
from the ball storage portion and in which second gate device is
disposed; and, FIG. 5B is a schematically longitudinal section view
of the above extended end portion of the ball delivery device;
[0042] FIG. 6A is a schematically horizontal section view of ball
passage number count device; and, FIG. 6B is a schematically
longitudinal section view of the ball passage number count
device;
[0043] FIG. 7A is a schematically longitudinal section view of the
main portions of hand-operated ball supply device; and, FIG. 7B is
a partially enlarged longitudinal section view of part of the above
main portions;
[0044] FIG. 8 is an explanatory plan view of an embodiment of an
apparatus for assembling a ball screw apparatus according to the
invention;
[0045] FIG. 9 is a front view of FIG. 8;
[0046] FIG. 10A is an explanatory view of a ball insertion jig;
FIG. 10B is a view of the ball insertion jig, when it is viewed
from the right side of FIG. 10A; and, FIG. 10C is a view of the
ball insertion jig, when it is viewed from the top side of FIG.
10A;
[0047] FIG. 11 is an explanatory view of the main portions of the
apparatus for assembling a ball screw apparatus; in particular, an
explanatory section view of a nut and a ball insertion jig, when
they are viewed from the lateral side thereof;
[0048] FIG. 12A is an explanatory section view of the nut and ball
insertion jig, when they are viewed from the top side thereof; and,
FIG. 12B is a section view taken along the line A-A shown FIG.
12A;
[0049] FIG. 13A is an explanatory view of the operation of the
apparatus for assembling a ball screw apparatus; in particular, an
explanatory section view of a nut and a ball insertion jig, when
they are viewed from the lateral side thereof; and, FIG. 13B is a
section view taken along the line B-B shown in FIG. 13A;
[0050] FIG. 14 is an explanatory view of a floating mechanism;
and,
[0051] FIG. 15 is an explanatory view of another embodiment of an
apparatus for assembling a ball screw apparatus according to the
invention; in particular, FIG. 15A is a view of a provisional
shaft, showing a state in which an elastic member is disposed on
the entire outer peripheral surface of the provisional shaft; and,
FIG. 15B is a view of the provisional shaft, showing a state in
which an elastic member is spirally disposed on the outer
peripheral surface of the provisional shaft.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0052] Firstly, description will be given below schematically of
the whole structure of an embodiment of a ball given quantity
supply apparatus according to the invention with reference to FIG.
1. By the way, FIG. 1 is a schematically perspective view of the
whole of the above embodiment.
[0053] A ball given quantity supply apparatus according to the
present embodiment supplies a given quantity of balls to an
apparatus which uses a given quantity of balls, for example, a
bearing, a ball screw and a linear guide. And, according to the
present ball given quantity supply apparatus, even in case where
the above balls are covered with oil having a relatively high
coefficient of viscosity such as anticorrosive oil, positive and
quick supply of the above-mentioned given quantity of balls is
always possible.
[0054] The present ball given quantity supply apparatus comprises a
ball storage portion 10 for storing a plurality of balls therein.
In the ball storage portion 10, there is disposed ball arranging
device 12 for arranging the plurality of balls stored in the ball
storage portion 10 in a line.
[0055] A ball delivery device 14 is extended from the ball storage
portion 10. The ball delivery device 14 includes a ball passage to
which the plurality of balls arranged in a line by the ball
arranging device 12 are supplied and also through which the
plurality of balls are allowed to pass in a line. The plurality of
balls in a line in the ball passage are delivered from the ball
storage portion 10 toward the extended end portion thereof due to
gravity.
[0056] At the position of the ball passage of the ball delivery
device 14 that is situated near to the ball storage portion 10,
there is disposed first gate device 16 which is used to open and
close the ball passage. And, at the position of the ball passage of
the ball delivery device that is situated more distant from the
ball storage portion 10 than the first gate device 16, there is
disposed second gate device 18. The second gate device 18 opens and
closes the ball passage to thereby hold a given quantity of balls
between the first gate device 16 and itself. In the present
embodiment, the first gate device 16 and second gate device 18 can
be respectively driven using a pressurized fluid.
[0057] In the portion of the ball passage of the ball delivery
device 14 that is present in the vicinity of the first gate device
16, there is disposed pressurized fluid jetting device 20. The
pressurized fluid jetting device 20 jets out a pressurized fluid
onto balls passing through the ball passage to thereby separate
substances attached to the surfaces of the balls from these
surfaces.
[0058] The operations of the first and second gate device 16 and 18
can be controlled by operation control device 22. The operation
control device 22 is able to detect that a given quantity of balls
are held between the first and second gate device 16 and 18 in the
ball passage of the ball delivery device 14.
[0059] And, the operation control device 22, while a plurality of
balls arranged in a line by the ball arranging device 12 are being
supplied into the ball passage of the ball delivery device 14,
opens the first gate device 16 and closes the second gate device
18; and, after it detects that a given quantity of balls are held
between the first and second gate device 16 and 18 in the ball
passage of the ball delivery device 14, it closes the first gate
device 16 and, at the same time when the first gate device 16 is
closed, or after passage of a given period of time set by a timer
(not shown) after the first gate 16 is closed, it opens the second
gate 18.
[0060] The extended end of the ball passage of the ball delivery
device 14 is connected through a ball supply tube 24 to a ball
insert apparatus (not shown) which receives a given quantity of
balls from the above ball given quantity supply apparatus and
inserts a given quantity of balls into an apparatus using a given
quantity of balls such as a bearing, a ball screw and a linear
guide.
[0061] To the portion of the ball passage of the ball delivery
device 14 that is present downstream of the second gate device 18,
there is connected hand-operated ball supply device 26 so as to
communicate with the present ball passage portion.
[0062] In the portion of the ball passage of the ball delivery
device 14 that is situated more downstream of the communicating
portion of the hand-operated ball supply device 26, there is
disposed ball passage number count device 28 which is used to count
the number of balls that passes through the ball passage.
[0063] Next, description will be given below in detail of the
details of the structure of the ball given quantity supply
apparatus according to the invention, which is described above with
reference to FIG. 1, with reference to FIG. 1 and the remaining
drawings as the need arises. By the way, FIG. 2A is a schematically
longitudinal section view of the ball storage portion 10, taken
along the line II(A)-II(A) shown in FIG. 1; and, FIG. 2B is a
schematically transverse section view of the ball storage portion
10, taken along the line II(B)-II(B) shown in FIG. 1.
[0064] The ball storage portion 10 includes a ball receiving
recessed portion 10a for receiving a plurality of balls B; and, the
ball receiving recessed portion 10a has a structure in which a
plurality of balls B stored in the ball receiving recessed portion
10a can be arranged due to gravity along a given area of the inner
peripheral surface of the ball receiving recessed portion 10a.
[0065] In more detail, the ball receiving recessed portion 10a of
the ball storage portion 10 according to the present embodiment has
a square-shaped flat surface shape, while one side (which is
hereinafter referred to as a first side) of the inner peripheral
surface of the ball receiving recessed portion 10a constitutes the
above-mentioned given area; and, on the above-mentioned inner
peripheral surface, at a given position of the above-mentioned
inner peripheral surface which is situated in the vicinity of the
upper end of one side 10d (which is hereinafter referred to as a
second side) of two sides intersecting the first side 10c and also
is present along the first side 10c, there is formed a ball supply
opening 10e serving as a base end from which the ball delivery
device 14 is extended.
[0066] The bottom wall of the ball storage portion 10 includes a
first bottom wall area 10f situated near to the second side 10d and
a second ball wall area 10g distant from the second side 10d. The
first bottom wall area 10f and second bottom wall area 10g, as
shown in FIG. 2B, are respectively inclined downwardly as they
approach the first side 10c. And, the inclination angle a thereof
is set in such a manner that, even in case where a plurality of
balls B stored in the ball receiving recessed portion 10a of the
ball storage portion 10 are covered with oil having a relatively
high coefficient of viscosity such as anticorrosive oil so as to be
supplied to e.g. a bearing, a ball screw and a linear guide, the
balls B arranged on the first bottom wall area 10f and second
bottom wall area 10g are allowed to move positively toward the
first side 10c due to gravity.
[0067] The first bottom wall area 10f and second bottom wall area
10g, as shown in FIG. 2A, are further respectively inclined
downwardly as they approach the second side 10d, while the
inclination angle .beta.2 of the second bottom wall area 10g is set
larger than the inclination angle .beta.1 of the first bottom wall
area 10f. The inclination angles .beta.1 and .beta.2 are
respectively set in such a manner that, even in case where a
plurality of balls B stored in the ball receiving recessed portion
10a of the ball storage portion 10 are covered with oil having a
relatively high coefficient of viscosity such as anticorrosive oil
to be supplied to e.g. a bearing, a ball screw and a linear guide,
the balls B arranged on the first bottom wall area 10f and second
bottom wall area 10g are allowed to move positively toward the
first side 10c due to gravity.
[0068] As can be seen clearly from the foregoing detailed
description, in the ball storage portion 10 according to the
present embodiment, since the first bottom wall area 10f and second
bottom wall area 10g of the ball receiving recessed portion 10a are
respectively inclined in the above-mentioned manner, even in case
where a plurality of balls B stored in the ball receiving recessed
portion 10a of the ball storage portion 10 are covered with oil
having a relatively high coefficient of viscosity such as
anticorrosive oil so as to be supplied to e.g. a bearing, a ball
screw and a linear guide, the balls B can be arranged along the
first side 10c, which constitutes the given area of the inner
peripheral surface of the ball receiving recessed portion 10a, due
to gravity.
[0069] The ball arranging device 12, which is used to arrange a
plurality of balls B stored in the ball storage portion 10 in a
line, includes a plate-shaped ball gather-up member 12a which can
be moved up and down in a given range along the first side 10c. The
ball gather-up member 12a extends along the portion of the first
side 10c that corresponds to the first bottom wall area 10f and, as
shown by solid lines in FIGS. 2A and 2B, can be moved up and down
between a lower end position and an upper end position by
conventionally-known vertically driving device (not shown): that
is, the lower end position is a position in which the upper end
face 12b of the ball gather-up member 12a is situated slightly
downwardly of the side edge of the first bottom wall area 10f along
the first side 10c; and, the upper end position is a position in
which the upper end face 12b is made to correspond to the lower end
of the opening 10e of the second side 10d of the inner peripheral
surface of the ball storage portion 10.
[0070] The upper end face 12b of the ball gather-up member 12a has
a width T larger than the radius of the ball B. Also, the upper end
face 12b, as shown clearly in FIGS. 2A and 2B, is inclined
similarly to the first bottom wall area 10f. That is, the upper end
face 12b is inclined in such a manner that it goes downwardly not
only as it approaches the first side 10c but also as it approaches
the second side 10d.
[0071] The ball arranging device 12 further includes a ball
restricting member 12c which is fixed to the first side 10c in such
a manner that it is spaced upwardly by a given distance from the
upper end face 12b of the ball gather-up member 12a held at the
upper end position. The ball restricting member 12c includes a
lower end face 12d which extends in parallel to the upper end face
12b in such a manner that it is spaced upwardly by a given distance
from the upper end face 12b of the ball gather-up member 12a held
at the upper end position. The above-mentioned given distance is a
distance which is slightly larger than the diameter of the ball B;
and, the lower end face 12d as well, similarly to the upper end
face 12b of the ball gather-up member 12a, has a width T larger
than the radius of the ball B. The lower end face 12d further, as
clearly shown in FIGS. 2A and 2B, similarly to the upper end face
12b of the ball gather-up member 12a, is inclined downwardly not
only as it approaches the first side 10c but also as it approaches
the second side 10d. And, the inclination angle of the lower end
surface 12d of the ball restricting member 12c with respect to the
first side 10c is set smaller than the inclination angle of the
upper end face 12b of the ball gather-up member 12a.
[0072] According to the ball arranging device 12 structured in this
manner, while a plurality of balls B stored in the ball receiving
recessed portion 10a of the ball storage portion 10 being arranged
due to gravity along the first side 10c constituting the given area
of the inner peripheral surface of the ball receiving recessed
portion 10a in the above-mentioned manner, the ball gather-up
member 12a is moved upwardly from the lower end position to the
upper end position to thereby be able to gather the plurality of
balls B situated on the upper end face 12b of the ball gather-up
member 12a along the first side 10c up to the upper end position.
The number of balls B that can be arranged on the upper end face
12b of the ball gather-up member 12a can be set arbitrarily
according to the diameter of the ball B and the length of the
portion of the upper end face 12b that extends along the first side
10c.
[0073] In case where the ball gather-up member 12a approaches the
upper end position, even when a plurality of balls B are arranged
in a plurality of stages in the vertical direction on the upper end
face 12b of the ball gather-up member 12a, other balls B than a
given number of balls B arranged directly on the upper end face 12b
of the ball gather-up member 12a in a line on the first stage, as
shown by the arrow mark D in FIG. 2B, are pushed down into the ball
receiving recessed portion 10a of the ball storage portion 10 by
the lower end face 12d of the ball restricting member 12c.
[0074] That is, at the time when the ball gather-up member 12a
reaches the upper end position, as clearly shown in FIG. 2A, on the
upper end face 12b of the ball gather-up member 12a, there are
arranged a given number of balls B in a line.
[0075] The above functions, which are provided by the ball
gather-up member 12a and ball restricting member 12c of the ball
arranging device 12, are fulfilled quickly and positively even in
case where the balls B are balls which are covered with oil having
a relatively high coefficient of viscosity such as anticorrosive
oil so as to be supplied to e.g. a bearing, a ball screw and a
linear guide.
[0076] And, after the ball gather-up member 12a reaches the upper
end position, a given number of balls B arranged on the upper end
face 12b of the ball gather-up member 12a can be supplied into the
ball supply opening 10e of the second side 10d of the ball
receiving recessed portion 10a of the ball storage portion 10 due
to gravity. This ball supply is also carried out quickly and
positively even in case where the balls B are balls which are
covered with oil having a relatively high coefficient of viscosity
such as anticorrosive oil so as to be supplied to e.g. a bearing, a
ball screw and a linear guide.
[0077] According to the present embodiment, the ball arranging
device 12, as shown in FIG. 1, further includes ball forced supply
device 13 which can forcibly supply a given number of balls B,
which are arranged in a line by the ball arranging device 12 as
described above, into the ball passage of the ball delivery device
14 extended from the ball supply opening 10e more quickly and
positively.
[0078] The ball forced supply device 13, as shown in FIGS. 2A and
2B, includes a guide rail member 13a fixed to the upper portion of
the ball restricting member 12c in the first side 10c of the inner
peripheral surface of the ball receiving recessed portion 10a of
the ball storage portion 10. The guide rail member 13a includes a
guide rail (not shown) which extends in parallel to the lower end
face 12d of the ball restricting member 12c, that is, the upper end
face 12b of the ball gather-up member 12a.
[0079] The ball forced supply device 13, as shown in FIG. 1,
further includes a ball push-in member 13b the movement of which
can be guided by the guide rail of the guide rail member 13a. When
it is guided by the guide rail, the ball push-in member 13b can be
moved through a clearance having the above-mentioned given distance
between the upper end face 12b of the ball gather-up member 12a
held at the upper end position and the lower end face 12d of the
ball restricting member 12c along the first side 10c, upper end
face 12b and lower end face 12d.
[0080] The ball forced supply device 13, as shown in FIG. 1, still
further includes a linear reciprocation drive device 13c which is
fixed to the first side 10c on the distant side from the second
side 10d with respect to the ball restricting member 12c. According
to the present embodiment, the linear reciprocation drive device
13c is composed of a piston-cylinder unit which can be driven using
pressurized fluid pressure. The linear reciprocation drive device
13c is connected to the ball push-in member 13b and, while the ball
gather-up member 12a is not held at the upper end position,
separates the ball push-in member 13b from the clearance having the
above-mentioned given distance between the upper end face 12b of
the ball gather-up member 12a held at the upper end position and
the lower end face 12d of the ball restricting member 12c on the
distant side from the second side 10d with respect to the ball
restricting member 12c.
[0081] And, in case where the ball gather-up member 12a is moved
from the lower end position toward the upper end position and
reaches the upper end position, the linear reciprocation drive
device 13c of the ball forced supply device 13 pushes out the ball
push-in member 13b into the clearance of the above-mentioned given
distance between the upper end face 12b of the ball gather-up
member 12a held at the upper end position and the lower end face
12d of the ball restricting member 12c, and allows the ball push-in
member 13b to move forwardly until it reaches the ball supply
opening 10e. In addition to the action of gravity, due to such
forward motion of the ball push-in member 13b, a given number of
balls B arranged on the upper end face 12b of the ball gather-up
member 12a after it reaches the upper end position can be forcibly
supplied more quickly and positively into the ball supply opening
10e of the second side 10d of the ball receiving recessed portion
10a of the ball storage portion 10.
[0082] After the ball push-in member 13b reaches the ball supply
opening 10e, while the ball gather-up member 12a is lowered down to
the lower end position and is raised up to the upper end position
again, the linear reciprocation drive device 13c of the ball forced
supply device 13 drives the ball push-in member 13b to move
backwardly, that is, move away from the clearance of the
above-mentioned given distance between the upper end face 12b of
the ball gather-up member 12a held at the upper end position and
the lower end face 12d of the ball restricting member 12c to the
distant side from the second side 10d with respect to the ball
restricting member 12c.
[0083] Next, description will be given below in detail of structure
of the ball delivery device 14 that is extended from the ball
supply opening 10e of the second side 10d of the ball storage
portion 10 with reference to FIGS. 1 and 3. By the way, FIG. 3 is a
schematically transverse section view taken along the line III-III
shown in FIG. 1.
[0084] The ball delivery device 14 includes a base member 14a
extended from the lower end of the ball supply opening 10e of the
second side 10d of the ball storage portion 10, a side plate 14b
fixed to one side edge of the base member 14a and extended from and
along the present one side edge of the ball supply opening 10e, and
a cover 14c placed over the upper surface of the base member 14a
and extended from the upper end of the ball supply opening 10e
along the present upper surface.
[0085] Referring to the structure of the upper surface of the base
member 14a, the area 14a' thereof situated next to the side plate
14b, as shown clearly in FIG. 3, is inclined downwardly as it
approaches the side plate 14b and also is inclined downwardly as it
goes away from the ball supply opening 10e. And, the present upper
surface is curved in such a manner that it goes downwardly in the
portion thereof situated near to the extended end of the base
member 14a.
[0086] The area 14c' of the cover 14c facing the area 14a' of the
base member 14a, as shown in FIG. 3, is cut away into a square
shape. The square-shaped area 14c' of the cover 14c is extended
along the area 14b' of the upper surface of the base member 14a
from the ball supply opening 10e up to the extended end of the area
14b'.
[0087] The side surface of the side plate 14b on the base member
14a side, the area 14a' of the base member 14a, and the area 14c'
of the cover 14c, as shown in FIG. 3, cooperate together in forming
a ball passage 14d having a substantially square-shaped cross
section, while the ball passage 14d has a width and a height both
slightly larger than the diameter of the ball B. And, the ball
passage 14d having a substantially square-shaped cross section
generates, between the outer peripheral surfaces of the balls B
passing through the ball passage 14d and the four corners of the
section of the ball passage 14d, fluid passage clearances which
allow a fluid to pass easily therethrough.
[0088] The balls B supplied from the ball supply opening 10e of the
second side 10d of the ball storage portion 10 into the ball
passage 14d of the ball delivery device 14 are rolled on the area
14a' of the upper surface of the base member 14a down to the
extended end of the ball passage 14d due to the above-mentioned
inclination and action of gravity in the extended direction of the
area 14a' of the upper surface of the base member 14a, whereby the
balls B can be delivered. Such delivery of the balls B through the
passage 14d can be carried out quickly and positively even when the
balls B are balls which are covered with oil having a relatively
high coefficient of viscosity such as anticorrosive oil and are to
be supplied to e.g. a bearing, a ball screw and a linear guide.
[0089] The fluid passage clearances in the four corners of the
cross section of the ball passage 14d can further facilitate the
above delivery of the balls B. Also, since the downward inclination
of the area 14a' of the upper surface of the base member 14a toward
the side plate 14b causes the balls B during the above delivery to
be always contacted with the side plate 14b, the balls B during the
above delivery can be always contacted with the area 14a' of the
upper surface of the base member 14a and side plate 14b at two
points. This can stabilize the motion of the balls B during the
above delivery; and thus, the above delivery can be carried out
smoothly, quickly and positively. Further, simply by changing the
dimensions of the cross section of the cut-away portion of the area
14c' of the cover 14c, the above-structured ball passage 14d
enables even balls B having various diameters to be delivered
easily with the above-mentioned various effects.
[0090] In addition, the cut-away portion of the area 14c' of the
cover 14c can be structured in such a manner that the cross section
of the ball passage 14d can have any one of various polygonal
shapes including a triangle or more.
[0091] In the present embodiment, the length of the area of the
ball passage 14d between the first gate device 16 and second gate
device 18 is set substantially equal to the sum of the diameters of
a given number of balls B to be arranged in a line on the upper end
face 12b of the ball gather-up member 12a of the ball arranging
device 12. In other words, this means that, in the area of the ball
passage 14d between the first gate device 16 and second gate device
18, there can be held a given number of balls B to be arranged in a
line on the upper end face 12b of the ball gather-up member 12a of
the ball arranging device 12.
[0092] Next, description will be given below in more detail of the
respective structures of the pressurized fluid jetting device 20
and operation control device 22 with reference to not only FIG. 1
but also FIGS. 4A, 4B and FIGS. 5A, 5B.
[0093] Here, FIG. 4A is a schematically horizontal section view of
not only the base end portion of the ball delivery device 14 which
is situated in the vicinity of the ball storage portion 10 and also
in which the first gate device 16 and pressurized fluid jetting
device 20 are disposed, but also the portion of the ball storage
portion 10 that adjoins the present base end portion; and, FIG. 4B
is a schematically longitudinal section view of the above base end
portion of the ball delivery device 14 and the portion of the ball
storage portion 10 adjoining the present base end portion.
[0094] Also, FIG. 5A is a schematically horizontal section view of
the extended end portion of the ball delivery device 14 which is
distant from the ball storage portion 10 and also in which the
second gate device 18 is disposed; and, FIG. 5B is a schematically
longitudinal section view of the above extended end portion of the
ball delivery device 14.
[0095] Referring to the structure of the pressurized fluid jetting
device 20, as shown in FIGS. 4A and 4B, in the ball passage 14d of
the ball delivery device 14, there is formed a jet-out opening in
the upper corner portion of one inside surface of the ball passage
14d on the delivery direction side of the balls B in the ball
passage 14d with respect to the first gate device 16. This jet-out
opening faces in a direction which is inclined from the crossing
direction of the ball passage 14 toward the above delivery
direction.
[0096] A pressurized fluid, which is jetted out from the jet-out
opening of the pressurized fluid jetting device 20, not only
separates various substances attached to the surfaces of the balls
B passing in front of the jet-out opening such as the
above-mentioned oil from the present surfaces to a considerable
degree but also forcibly discharges the above attached substances
separated from the surfaces of the balls B up to the extended end
of the ball passage 14d through spaces existing in the four corner
portions of the cross section of the ball passage 14d.
[0097] Further, since the jet-out opening of the pressurized fluid
jetting device 20 is inclined toward the above-mentioned delivery
direction, not only the balls B supplied from the ball supply
opening 10e of the second side 10d of the ball storage portion 10
can be prevented from being blown back toward the ball supply
opening 10e by the pressurized fluid jetted out from the jet-out
opening; but also, the quick supply of the balls B from the ball
supply opening 10e into the ball passage 14d can be prevented from
being made difficult.
[0098] According to the present embodiment, in the ball passage 14a
of the ball delivery device 14, there are disposed two pressurized
fluid discharge device 14e respectively at a position in the
vicinity of the first gate device 16 and at a position nearer to
the extended end portion of the ball delivery device 14 than the
second gate device 16. The pressurized fluid discharge device 14e
are used to discharge the pressurized fluid jetted out from the
pressurized fluid jetting device 20 into the ball passage 14a to
the outside of the ball passage 14a.
[0099] In more detail, as shown in FIG. 3 especially clearly, each
of the pressurized fluid discharge device 14e is composed of a
cut-away portion which is formed at a given position of the side
surface of the cover 14c of the ball delivery device 14 that is
contacted with the side wall 14b and also which penetrates through
between the upper surface of the ball passage 14a and the upper
surface of the cover 14c.
[0100] These pressurized fluid discharge device 14e relieve the
sucking action of the pressurized fluid jetted out from the jet-out
opening of the pressurized fluid jetting device 20 in the ball
passage 14a of the ball delivery device 14, while the sucking
action is an action which, based on the Bernoulli's theorem, is
applied to the balls B passing in front of the pressurized fluid by
the pressurized fluid. Such relief of the sucking action not only
can avoid a possibility that, depending on the quantity and speed
per unit time of the pressurized fluid jetted out from the jet-out
opening, the balls B passing in front of the jet-out opening can be
sucked by the jet-out opening and the delivery of the balls B in
the ball passage 14a can be thereby stopped, but also permits the
full display of the separating function of the pressurized fluid
jetted out from the jet-out opening of the pressurized fluid
jetting device 20 that separates various substances such as the
above-mentioned oil attached to the surfaces of the balls B being
delivered in the ball passage 14 from the present balls B
surfaces.
[0101] The pressurized fluid discharge device 14e, especially, the
pressurized fluid discharge device 14e situated in the vicinity of
the second gate device 18 can further eliminate the possibility
that the delivery speed of the balls B being delivered in the ball
passage 14a can be increased by the pressurized fluid jetted out
from the jet-out opening of the pressurized fluid jetting device 20
into the ball passage 14a and thus the balls B can be struck
strongly against something such as the inner surface of the
downward curved portion of the extended end portion of the ball
passage 14a or the balls B can be collided with each other to be
thereby damaged.
[0102] By the way, the pressurized fluid jetting device 20 can also
be structured such that it can jet out the pressurized fluid
intermittently. The intervals, start and end of the intermittent
jetting-out operation of the pressurized fluid can be set
arbitrarily.
[0103] The intermittent jetting operation of the pressurized fluid
by the pressurized fluid jetting device 20, similarly to the
pressurized fluid discharge device 14e, also relieves the sucking
action of the pressurized fluid jetted out from the jet-out opening
of the pressurized fluid jetting device 20 in the ball passage 14a
of the ball delivery device 14, while the sucking action is an
action which, based on the Bernoulli's theorem, is applied to the
balls B passing in front of the pressurized fluid by the
pressurized fluid. Such relief of the sucking action not only can
avoid a possibility that, depending on the quantity and speed per
unit time of the pressurized fluid jetted out from the jet-out
opening, the balls B passing in front of the jet-out opening can be
sucked by the jet-out opening and the delivery of the balls B in
the ball passage 14a can be thereby stopped, but also permits the
full display of the separating function of the pressurized fluid
jetted out from the jet-out opening of the pressurized fluid
jetting device 20 that separates various substances such as the
above-mentioned oil attached to the surfaces of the balls B being
delivered in the ball passage 14 from the present balls B
surfaces.
[0104] The operation control device 22 includes a first ball
detector 22a disposed in the ball passage 14a of the ball delivery
device 14 so as to adjoin the downstream side of the first gate
device 16, and a second ball detector 22b disposed so as to adjoin
the upstream side of the second gate device 18. In the present
embodiment, the operation control device 22 further includes a
third ball detector 22c disposed in the ball passage 14a of the
ball delivery device 14 so as to adjoin the upstream side of the
first gate 16.
[0105] As the first to third ball detectors 22a, 22b and 22c, there
can be used various kinds of detectors, provided that they are able
to detect positively the balls B passing just in front of them in
the ball passage 14a. In case where the balls B are made of metal,
as the first to third ball detectors 22a, 22b and 22c, there can be
used metal approach detectors; and, in case where the balls B are
made of metal or nonmetal, there can also be used optical
detectors. Also, the first to third ball detectors 22a, 22b and 22c
may be detectors of the same kind or detectors of different
kinds.
[0106] By the way, even in case where the balls B passing through
the ball passage 14a of the ball delivery device 14 are balls which
are covered with oil having a relatively high coefficient of
viscosity such as anticorrosive oil so as to be supplied to e.g. a
bearing, a ball screw and a linear guide, since the pressurized
fluid blown into the ball passage 14a by the pressurized fluid
jetting device 20 can separate the above-mentioned oil attached to
the balls B to a considerable degree, the precision of the first to
third ball detectors 22a, 22b and 22c can be always maintained at a
high level.
[0107] Next, description will be given below in detail of the ball
passage number count device 28 with reference to FIG. 1 as well as
FIGS. 6A and 6B.
[0108] Here, FIG. 6A is a schematically horizontal section view of
the ball passage number count device 28; and, FIG. 6B is a
schematically longitudinal section view of the ball passage number
count device 28.
[0109] The ball passage number count device 28 is interposed
between the extended end of the ball passage 14a of the ball
delivery device 14 and ball supply tube 24. The ball passage number
count device 28 includes a count device hold member 28b having a
ball passage 28a which allows the extended end of the ball passage
14a of the ball delivery device 14 and ball supply tube 24 to
communicate with each other. The cross section shape and dimension
of the ball passage 28a are substantially equal to the cross
section shape and dimension of the ball passage 14a of the ball
delivery device 14. That is, the cross section shape of the ball
passage 28a is a rectangular shape which has length and width
dimensions slightly larger than the diameter of the balls B.
[0110] In the ball passage 28a, there is disposed a ball passage
detector 28c which is capable of detecting that the balls B passes
through the ball passage 28a. In the present embodiment, the ball
passage detector 28c is composed of a pair of optical sensors
respectively connected to the operation control device 22. However,
in case where the balls B are made of metal, there can also be used
a metal approach detector. The pair of optical sensors are shut off
from the light by the ball B each time the ball B passes through
the ball passage 28a and they transmit signals generated as a
result of this to the operation control device 22; and, count
device (not shown) included in the operation control device 22,
based on the above signals, counts the number of balls B that
passes through the ball passage 28a.
[0111] The ball passage number count device 28 further includes a
pair of pressurized fluid jet-out holes 28d which jet out the
pressurized fluid toward the pair of optical sensors in the ball
passage 28a.
[0112] The pressurized fluids jetted out from the pair of
pressurized fluid jet-out holes 28d prevent dirty substances from
being attached to the pair of optical sensors and thus can prevent
the malfunction of the pair of the optical sensors. The jetting of
the pressurized fluids from the pair of pressurized fluid jet-out
holes 28d is carried out during the time after the ball passage
number count device 28 counts the passage of a given number of
balls B through the ball passage 28a before a next given number of
balls B are supplied into the ball passage 28a, in order to be able
to prevent the present pressurized fluid jetting from impeding the
quick passage of the balls B in the ball passage 28a. Such
pressurized fluid jetting may be carried out continuously or
intermittently. That is, in the case of the ball passage number
count device 28 according to the present embodiment, even in case
where the balls B passing through the ball passage 28a are balls
which are covered with oil having a relatively high coefficient of
viscosity such as anticorrosive oil so as to be supplied to e.g. a
bearing, a ball screw and a linear guide, thanks to the pressurized
fluids jetted out from the pair of pressurized fluid jet-out holes
28d, dirt including the above-mentioned oil can be prevented from
sticking to the pair of optical sensors, which allows the pair of
optical sensors to always operate with good precision.
[0113] Next, description will be given below in detail of the
structure of the hand-operated ball supply device 26 with reference
to FIGS. 7A and 7B.
[0114] Here, FIG. 7A is a schematically longitudinal section view
of the main portions of the hand-operated ball supply device 26;
and, FIG. 7B is a partially enlarged longitudinal section view of
part of the above main portions.
[0115] In the present embodiment, the hand-operated ball supply
device 26 includes a funnel-shaped ball throw member 26a and a ball
guide member 26b which is extended from the central portion of the
bottom surface of the ball throw member 26a to the downstream side
of the second gate device 18 in the ball passage 14a of the ball
delivery device 14 and is allowed to communicate with the present
downstream side. And, the communicating position of the ball guide
member 26 with respect to the ball passage 14a of the ball delivery
device 14 is set between the extended end of the ball passage 14a
of the ball delivery device 14 and ball passage number count device
28.
[0116] That is, the number of balls B supplied by hand to the
extended end of the ball passage 14a of the ball delivery device 14
through the hand-operated ball supply device 26 can also be counted
accurately by the ball passage number count device 28.
[0117] In the present embodiment, the hand-operated ball supply
device 26 further includes ball mixing device 26c which mixes a
plurality of balls B thrown into the ball throw member 26a in the
central portion of the bottom surface of the ball throw member 26a
to thereby prevent the plurality of balls B from being clogged in
the entrance of the ball guide member 26b in the present central
portion. The ball mixing device 26c comprises a motor 26d including
an output shaft having a rotation center axis R eccentric to the
center C of the entrance of the ball guide member 26b in the
central portion of the bottom surface of the ball throw member 26a,
and a mixing rod 26e eccentrically fixed to the above output shaft.
In case where the output shaft of the motor 26d is rotated in a
given direction, as shown clearly in FIG. 7B, the mixing rod 26e
moves around the output shaft of the motor 26d having a rotation
center axis R eccentric to the center C of the entrance of the ball
guide member 26b in the central portion of the bottom surface of
the ball throw member 26a.
[0118] The locus of the movement of the mixing rod 26e around the
output shaft crosses the entrance of the ball guide member 26b in
the central portion of the bottom surface of the ball throw-in
member 26a.
[0119] Into the ball throw member 26a of the hand-operated ball
supply device 26, there can be thrown a given number of balls B
using a known ball given quantity plate 26f. The given number of
balls B thrown into the ball throw member 26a are allowed to roll
toward the entrance of the ball guide member 26b in the central
portion of the bottom surface of the ball throw member 26a due to
gravity, and move one by one into the ball guide member 26b through
the above entrance. During this, there is a possibility that the
given number of balls B collecting together in the entrance can be
butted against each other to thereby prevent each other from moving
into the ball guide member 26 through the entrance. However, such
mutual butting between the given number of balls B in the entrance
can be solved immediately in case where they are mixed by the
eccentric mixing rod 26e of the ball mixing device 26c moving
around the output shaft of the motor 26d, so that the supply of the
given number of balls B one by one into the ball guide member 26b
through the entrance can be resumed immediately.
[0120] In the above-mentioned embodiment, all structures that can
operate using the pressurized fluid, that is, the linear
reciprocation drive device 13c of the ball forced supply device 13,
first and second gate device 16 and 18, pressurized fluid jetting
device 20, and the pair of pressurized fluid jet-out holes 28d of
the ball passage number count device 28 are allowed to communicate
with a pressurized fluid source 32 through a pressurized fluid
supply control device 30 including e.g. an electromagnetic valve
(not shown). The operation of the pressurized fluid supply control
device 30 is also controlled by the operation control device
22.
[0121] As the above-mentioned pressurized fluid, there can be
selected proper kinds of pressurized fluids according to the kinds
of the balls B that are supplied in the above-mentioned embodiment,
while the pressurized air is just a typical example.
[0122] Next, description will be given below of a series of
operations of the ball given quantity supply apparatus according to
the present embodiment structured in the above-described
manner.
[0123] As shown in FIGS. 2A and 2B, while a large number of balls B
are stored in the ball receiving recessed portion 10a of the ball
storage portion 10, the gather-up plate 12a of the ball arranging
device 12 is moved from the lower end position shown by a solid
line up to the upper end position shown by a two-dot chained line,
and a given quantity of balls B, that is, a given number of balls B
are arranged in a line on the upper end face 12b of the gather-up
plate 12a held at the upper end position.
[0124] After the gather-up plate 12a of the ball arranging device
12 is held at the upper end position, the linear reciprocation
drive device 13c of the ball forced supply device 13 shown in FIG.
1 pushes out the ball push-in member 13b toward the ball supply
opening 10e of the second side 10d of the ball storage portion 10.
As a result of this, a given quantity of, that is, a given number
of balls B arranged in a line on the upper end face 12b of the
gather-up plate 12a after it is held at the upper end position are
quickly and positively supplied in a line to the ball supply
opening 10e not only due to the action of gravity but also by the
ball push-in member 13b.
[0125] Here, in case where a given quantity of, that is, a given
number of balls B arranged in a line on the upper end face 12b of
the gather-up plate 12a after it is held at the upper end position
can be always moved quickly and positively toward the ball supply
opening 10e only due to the action of gravity, the operation of the
pressurized fluid supply control device 30 can also be controlled
by the operation control device 22 in such a manner that the linear
reciprocation drive device 13c of the ball forced supply device 13
does not push out the ball push-in member 13b toward the ball
supply opening 10e of the second side 10d of the ball storage
portion 10.
[0126] When the supply of the above-mentioned given quantity, that
is, the above-mentioned given number of balls B arranged in a line
to the ball supply opening 10e is started, the first and second
gate device 16, 18 close the ball passage 14d of the ball delivery
device 14.
[0127] In case where the third ball detector 22c adjoining the
upstream side of the first gate device 16 in the ball passage 14d
detects the balls B for the first time, as shown in FIGS. 4A and
4B, the first gate device 16 is opened and, at the same time, the
pressurized fluid jetting device 20 adjoining the downstream side
of the second gate device 16 starts to jet out the pressurized
fluid. This pressurized fluid jetting, as is described in detail of
the pressurized fluid jetting device 20 with reference to FIGS. 4A
and 4B, may be carried out continuously or intermittently according
to cases; and, the period of the continuous jetting as well as the
period of the intermittent jetting and the intervals between the
intermittent jetting operations can also be set freely by
controlling the operation of the pressurized fluid supply control
device 30 using the operation control device 22.
[0128] In the case of the above-mentioned given quantity, that is,
the above-mentioned given number of balls B in a line which passes
through the first gate device 16 in the ball passage 14d and also
from the surfaces of which the attached substances are separated to
a considerable degree by the pressurized fluid jetting device 20,
the delivery of the balls B in the ball passage 14d is stopped by
the second gate device 18 held at its closed position.
[0129] In case where not only the second ball detector 22b
adjoining the upstream side of the second gate device 18 held at
the closed position in the ball passage 14 detects the leading ball
B of the balls B in the above-mentioned line for a given period of
time or more but also the first ball detector 22a adjoining the
downstream side of the first gate device 16 at the open position in
the ball passage 14d detects the last ball B of the balls B in the
same line, it can be confirmed that the above-mentioned given
quantity, that is, the above-mentioned given number of balls B in a
line are held between the second gate device 18 at the closed
position and first gate device 16 at the open position in the ball
passage 14d.
[0130] By the way, in case where, after the second ball detector
22b adjoining the upstream side of the second gate device 18
detects the ball B for a given period of time or more, the first
ball detector 22a adjoining the downstream side of the first gate
device 16 does not detect the ball B for a given period of time or
more, it can be confirmed that a given number of balls B are not
stored in a given area between the second gate device 18 and first
gate device 16 in the ball passage 14d. That is, this means that a
given number of balls B arranged in a line by the ball arranging
device 12 are not supplied properly to the ball passage 14d through
the ball supply opening 10e of the ball storage portion 10.
[0131] In this case, while maintaining the open condition of the
first gate device 16 and the closed condition of the second gate
device 18, the supply of a plurality of balls B in a line arranged
by the ball arranging device 12 is to be carried out again.
[0132] To prevent such ball supply failure positively, after the
supply of a given number of balls B from the upper end face 12b of
the ball gather-up member 12a at the upper end position into the
ball passage 14d of the ball delivery device 14 is started, until
the first to third ball detectors 22a, 22b and 22c respectively
detect the balls B for a given period of time or more, while
maintaining the open condition of the first gate device 16 and the
closed condition of the second gate device 18, the supply of a
given number of balls B into the ball passage 14d of the ball
delivery device 14 by the ball gather-up member 12a should be
carried out repeatedly.
[0133] In case where the first and second ball detectors 22a and
22b detect the balls B for a given period of time or more, or, in
case where, as described above, the first to third ball detectors
22a, 22b and 22c respectively detect the balls B for a given period
of time or more, the first gate device 16 is moved to the closed
position and, at the same time, the second gate device 18 is moved
to the open position; or, after the passage of a given time set by
a timer (not shown) after the first gate device 16 is moved to the
closed position, the second gate device 18 is moved to the open
position; and, further, the ball gather-up plate 12a is returned
from the upper end position to the lower end position and, at the
same time, the ball push-in member 13b of the ball forced supply
device 13 is pulled back to its retreat position which is most
distant from the ball supply opening 10e of the second side 10d of
the ball storage portion 10.
[0134] In the case of the above-mentioned given quantity of, that
is, the above-mentioned given number of balls B in a line that
passes through the second gate device 18 which is opened, after
they pass through the extended end of the passage 14a of the ball
delivery device 14 and the number of the balls B in the line is
confirmed by the ball passage number count device 28, they are
supplied through the ball supply tube 24 into a ball inserting
apparatus (not shown) which is used to insert a given quantity of
balls into an apparatus using a given quantity of balls such as a
bearing, a ball screw and a linear guide.
[0135] By the way, the ball passage number count device 28 can also
be omitted and the counting of the ball passage number can also be
left stopped.
[0136] In case where the second ball detector 22b adjoining the
upstream side of the second gate device 18 at the open position in
the ball passage 14d fails to detect the passage of the
above-mentioned balls B in a line, the second gate device 18 is
moved from the open position to the closed position. Also, the
jetting of the pressurized fluid by the pressurized fluid jetting
device 20 is stopped. In the case of the intermitting jetting of
the pressurized fluid, after the second ball detector 22b fails to
detect the passage of the above balls B in a line, the pressurized
fluid is finally jetted out for a longer period of time than the
given period of time in the intermittent jetting and, after then,
the jetting of the pressurized fluid is stopped.
[0137] In the ball given quantity supply apparatus according to the
present embodiment, as can be seen clearly from the foregoing
detailed description of the hand-operated ball supply device 26
with reference to FIGS. 7A and 7B, a given quantity of, that is, a
given number of balls B can be manually supplied through the
hand-operated ball supply device 26 into a ball inserting apparatus
(not shown) which inserts a given quantity of balls into an
apparatus using a given quantity of balls such as a bearing, a ball
screw and a linear guide.
[0138] And, in this case as well, a given quantity of, that is, a
given number of balls B to be supplied from the hand-operated
supply device 26 to the above-mentioned ball inserting apparatus
(not shown), after the number of the above balls B in a line is
confirmed by the ball passage number count device 28, are supplied
through the ball supply tube 24 to the ball inserting apparatus
(not shown) which inserts a given quantity of balls into an
apparatus using a given quantity of balls such as a bearing, a ball
screw and a linear guide.
[0139] Further, description will be given below of the preferred
embodiments of an apparatus for assembling a ball screw apparatus
with reference to the accompanying drawings.
[0140] Here, FIG. 8 is an explanatory plan view of an apparatus for
assembling a ball screw apparatus according to an embodiment of the
invention; FIG. 9 is a front view of FIG. 8; FIG. 10A is an
explanatory view of a ball insertion jig; FIG. 10B is a view of the
ball insertion jig, when it is viewed from the right side of FIG.
10A; FIG. 10C is a view of the ball insertion jig, when it is
viewed from the upper side of FIG. 10A; FIG. 11 is an explanatory
section view of the main portions of the above apparatus for
assembling a ball screw apparatus, when a nut and a ball insertion
jig are viewed from the lateral side thereof; FIG. 12A is an
explanatory section view of the nut and ball insertion jig, when
they are viewed from above; FIG. 12B is a section view taken along
the A-A shown in FIG. 12A; FIG. 13A is an explanatory view of the
operation of the apparatus for assembling a ball screw apparatus,
when the nut and ball insertion jig are viewed from the lateral
side thereof; FIG. 13B is a section view taken along the line B-B
shown in FIG. 13A; FIG. 14 is an explanatory view of a floating
mechanism; and, FIG. 15 is an explanatory view of another
embodiment of an apparatus for assembling a ball screw apparatus
according to the invention.
[0141] The present apparatus for assembling a ball screw apparatus,
as shown in FIGS. 8 and 9, comprises: a provisional shaft 103, with
which a nut 101 of the ball screw apparatus with a circulating tube
(circulating part) 125 previously assembled thereto can be loosely
fitted; a floating mechanism 170 for clamping and holding the nut
101; a provisional shaft support part 109 for supporting the
provisional shaft 103 in such a manner that the left end side of
the provisional shaft 103 can be rotated; a ball insertion jig 104
fitted into between the provisional shaft 103 and nut 101 from the
left end side of the nut 101; a ball distribute and supply feeder
(not shown) for distributing a given number of balls from a ball
storage portion and supplying the balls into the ball insertion jig
104 through a ball chute 110; a screw shaft right end support part
108 for supporting the right end portion of a screw shaft 102 of
the ball screw apparatus engaged with the right end side of the
provisional shaft 103 in such a manner that the screw shaft right
end portion can be rotated; and, a drive motor (drive device) 111
connected through a coupling 134 to the left end portion of the
provisional shaft 103 to apply a rotational force to the
provisional shaft 103 and screw shaft 102.
[0142] The provisional shaft 109, floating mechanism 170 and screw
shaft right end support part 108 are respectively mounted on their
associated sliders 132 of a linear guide apparatus and are also
supported in such a manner that they can be moved in the axial
direction and can be positioned. By the way, of course, instead of
the linear guide apparatus, there can also be used a dovetail
groove or a V clamp.
[0143] Also, on one side of the ball chute 110, there is used a
transparent member (not shown) such as an acryl plate, thereby
being able to confirm whether a given number of balls are supplied
by the ball distributive take-out operation or not and also whether
any trouble is occurred or not when the balls are introduced, for
example, the balls are caught by something or not.
[0144] The provisional shaft 103, as shown in FIG. 11, includes a
small-diameter shaft portion 103a on the left end side thereof and
a large-diameter shaft portion 103b on the right end side thereof,
and includes further a tapered step portion 121 formed between
these two shaft portions. The large-diameter shaft portion 103b is
formed in a cylindrical shape, while a screw shaft 102 is inserted
into the interior of the large-diameter shaft portion 103b from the
right end side opening thereof; and, the screw shaft 102 is center
supported by a provisional shaft center support member 107 disposed
in the interior of the large-diameter shaft portion 103b. Also, the
large-diameter shaft portion 3b has a diameter which allows the
balls to be held on the BCD (ball center diameter) of the screw
groove 122 of the nut 101.
[0145] The ball insertion jig 104, as shown in FIGS. 10 and 11, is
formed in a cylindrical shape and is fitted into between the
provisional shaft 103 and nut 101 from the small-diameter shaft
portion 103a side of the provisional shaft 103. In the ball
insertion jig 104, there is formed a ball passage 126 which
penetrates through the ball insertion jig 104 in the axial
direction thereof; and, a given number of balls can be inserted
into the ball passage 126 from the ball chute 110.
[0146] And, in case where the provisional shaft 103 and screw shaft
102 are rotated (clockwise when viewed from the left end side; see
FIG. 13B) by the drive motor 111, the balls inserted into the ball
passage 126 are introduced through a guide portion 120a formed
between the guide surface 120 of the ball insertion jig 104 and the
tapered step portion 121 of the provisional shaft 103 into between
the screw groove 122 of the nut 101 and provisional shaft 103 as
well as into the circulating tube 125.
[0147] Here, the ball exit portion 123 of the ball passage 126 is
situated on the upper side in the peripheral direction of the screw
groove 122 so that the balls are allowed to flow easily through the
guide portion 120 due to their own weights down to the screw groove
122 of the nut 101.
[0148] The guide surface 120 of the ball insertion jig 104 is
inclined so that the balls can be introduced to the screw groove
122 of the nut 101; and thus, due to this, the balls inserted into
the ball passage 126 are allowed to flow into the screw groove 122
of the nut 101 while they roll down along the guide surface 120 and
are restricted by the tapered step portion 121 of the provisional
shaft 103.
[0149] On the ball exit opening 123 of the ball insertion jig 104,
as shown in FIGS. 10 and 12, there is disposed a ball stopper 127
which separates the exit side of the circulating tube 125 and guide
portion 120a from each other. The ball stopper 127 stops the
preceding balls previously introduced in the ball introduction
operation in the exit portion of the circulating tube 125 to
thereby prevent the preceding balls and the balls to be introduced
from the ball exit opening 123 from interfering with each
other.
[0150] Also, on the leading end portion of the ball stopper 127,
there is disposed a projection 128. The projection 128 changes the
advancing direction of the balls flowing from the ball passage 126
to thereby guide the balls along the guide portion 120a while
preventing the balls from touching directly the groove shoulder of
the screw groove 122 of the nut 101. Of course, the ball contact
portion of the projection 128 may also be in a cylindrical
shape.
[0151] By the way, as means for facilitating the introduction of
the balls, for example, an air jet-out opening (not shown) may be
formed in the leading end portion of the ball stopper 127. In this
case, after the balls are pushed out from the ball exit portion
123, the balls are easy to flow into the screw groove 122 along the
guide portion 120 by the air.
[0152] Also, there may also be provided a ball damper pin (not
shown) in the intermediate portion of the ball chute 110 so as to
dampen the speeds of the balls. In this case, it is possible to
prevent a large number of balls from being inserted at the same
time, which dampens impacts to be applied to the ball insertion jig
104, the groove shoulder of the screw groove 122 and balls
themselves by the drop of the balls due to their own weights to
thereby be able to prevent them against damage.
[0153] To clamp the nut 101 by the floating mechanism 170, as shown
in FIG. 14, for example, there are used ball plungers
117a.about.117e. That is, the ball plunger 117a pushes down the
upper end arc portion 130 of the nut 101 obliquely downwardly, so
that the nut 101 can be held easily. Of course, to hold the nut
101, there may also be used a clamp mechanism such as the air.
[0154] Also, the floating mechanism 170, using a micrometer 118a,
is capable of fine-adjust the eccentric amount of the nut 101 with
respect to the provisional shaft 103. For example, using a single
shaft slide unit 109, as shown in FIG. 13, the center of the nut
101 is pulled to the left by a spring (not shown) with respect to
the center of the provisional shaft 103 to shift the axis of the
nut with respect to the provisional shaft 103, thereby narrowing a
groove clearance between the nut 101 and the right side of the
provisional shaft 103. At the then time, since the provisional
shaft 103 is rotating clockwise, the balls introduced from the ball
insertion jig 104 are forcibly pushed into the screw groove
122.
[0155] Also, there is employed a structure in which, in case where
a groove clearance on the ball rising side is widened, the balls
can be pushed up successively while the balls can be prevented from
moving too early. Thanks to this structure, there can also be
expected an effect that the balls in the circulating tube 125 as
well can be pushed up successively.
[0156] That is, by shifting the nut 101 and provisional shaft 103
with respect to each other, while moving up the balls successively,
not only the too early movements of the balls can be prevented but
also the successive insertion of the balls can be attained. By the
way, in case where the clearance is widened too much, there is a
possibility that the balls can bite into something or can poke out
of the circulation passage; and, therefore, on the opposite side of
the micrometer 118a as well, there may be installed a micrometer
118b in order to be able to adjust the eccentric amount of the nut
101. Of course, the single shaft slide unit 119, alternatively, may
also be composed of a linear guide apparatus or the like. Also,
preferably, the heads of the two micrometers 118a, 118b
respectively may have rotation preventive mechanisms in their
associated thimble portions. By the way, in FIG. 14, reference
character 118a' designates a stopper on the micrometer 118a side,
while 118b' stands for a stopper on the micrometer 118b side.
[0157] Referring now to the screw shaft right end support part 108,
a left-going force is applied to it by a compression spring (moving
device) 115. This left-going force makes it possible to hold the
screw shaft 102 between the screw shaft right end support part 108
and the provisional shaft center support member 107 disposed in the
large-diameter shaft portion 103b of the provisional shaft 103.
[0158] And, in the provisional shaft support part 109, there is
disposed a member for positioning such as an air cylinder 112. To
adjust the moving range of the air cylinder 112, there are used a
micrometer 113 and a stopper 114. This makes it possible to
fine-tune the positioning of the tapered step portion 121 of the
provisional shaft 103 with respect to the guide surface 120 of the
ball insertion jig 104. A left-going force applied to the
provisional shaft support part 109 at the then time is composed of
a spring force given by a compression spring 115 disposed on the
screw shaft right end support part 108, whereas a right-going force
is composed of the air pressure of the air cylinder 112.
[0159] On the left end side of the passage portion where the ball
chute 110 and ball insertion jig 104 are contacted with each other,
there is disposed a ball push-out rod 105 which is supported on a
push-out rod support base 106. On the push-out rod support base
106, there is mounted a drive cylinder serving as a drive source
which is used to drive the ball push-out rod 105 to advance and
retreat. When a ball confirming sensor 124 disposed on the ball
chute 110 confirms that the balls are not present, the ball
push-out rod 105 is advanced to thereby push out all of the balls
existing within the ball passage 126 of the ball insertion jig 104
and, using a sensor disposed on the drive cylinder of the push-out
rod support base 106, it is detected that the balls existing within
the ball passage 126 are all pushed out therefrom.
[0160] The ball push-out rod 105 is caused to stop in a state where
it pushes out the balls existing in the ball passage 126 of the
ball insertion jig 104.
[0161] The reason for this is as follows. That is, to push up all
of the balls not introduced into the screw groove 122 of the nut
101 but left in the guide portion 120a between the guide surface
120 and the tapered step portion 121 of the provisional shaft 103
into the screw groove 122 of the nut 101 and to store them in the
screw groove 122, the air cylinder 112 is retreated and the
provisional shaft 103 is moved to the small-diameter shaft portion
103a, for example, by an amount corresponding to a half pitch using
the spring force of the compression spring 115 to thereby allow all
of the balls left in the guide portion 120a to climb over the
tapered step portion 121; that is, in this operation, in case where
the ball push-out rod 105 is caused to stop in a state where it
pushes out all of the balls, the ball push-out rod 105 can also be
used as a cover which prevents the balls from moving back again to
the ball exit portion of the ball passage 126. By the way, in order
to prevent the balls against damage, the air pressure may be used
only when returning the ball push-out rod 105, whereas the spring
(not shown) may be used when the ball push-out rod 105 pushes out
the balls from the ball passage 126 into the screw groove 122.
[0162] Also, in order to prevent the tongue portion of the
circulating tube 125 and the ball stopper 127 of the ball insertion
jig 104 from interfering with each other when allowing the balls
left in the guide portion 120a to climb over the tapered step
portion 121, the surface of the ball stopper 127 that faces the
exit side of the circulating tube 125 is formed as a flat surface
129.
[0163] Next, description will be given below of the operation of
the above-mentioned apparatus for assembling a ball screw
apparatus.
[0164] Firstly, to align the nut 101 of the ball screw apparatus
(in the present embodiment, there is used a cut formed in the outer
surface of the nut), the nut 101 is clamped by the floating
mechanism 170 according to a rail guide 131.
[0165] Next, a nut positioning air cylinder 133 is projected to
slide the floating mechanism 170 to the left, thereby positioning
the nut 101 with respect to the ball insertion jig 104. After then,
the screw shaft right end hold part 108 is moved to the right
against the energizing force of the compression spring 115 to
thereby hold the screw shaft 102 in a center support manner between
the screw shaft right end hold part 108 and center provisional
shaft center support member 107. At the then time, the eccentric
amount of the nut 101 with respect to the provisional shaft 103 is
adjusted by the micrometers 118a, 118b and stoppers 118a', 118b' of
the floating mechanism 170.
[0166] Next, a given number of balls supplied from the ball
distribution supply feeder are fed through the ball chute 110 into
the ball insertion jig 104. The balls fed into the ball insertion
jig 104 are allowed to pass through the ball passage 126 of the
ball insertion jig 104 and flow from the ball exit portion 123 into
the guide portion 120a between the tapered step portion 121 of the
provisional shaft 103 and the guide surface 120 of the ball
insertion jig 104.
[0167] Here, since the provisional shaft 103 is driven and rotated
clockwise by the drive motor 111, the balls flowing into the guide
portion 120a can be smoothly introduced into the screw groove 122
of the nut 101, while they are falling down due to their own
weights along the guide surface 120 of the ball insertion jig 104
under the restriction of the tapered step portion 121 of the
provisional shaft 103.
[0168] Next, in case where the ball confirming sensor 124 of the
ball chute 110 confirms no presence of the balls, the ball push-out
rod 105 is advanced to thereby push out all of the balls existing
in the ball passage 126 of the ball insertion jig 104; and, using
the sensor of the drive cylinder of the push-out rod support base
106, it is detected that the balls existing within the ball passage
126 are all pushed out therefrom. The ball push-out rod 105 stops
in the ball push-out completion state and functions as the cover of
the ball exit portion 123.
[0169] Next, the air cylinder 112 is retreated, the provisional
shaft 103 is moved to the small-diameter shaft portion 103a side by
an amount corresponding to, for example, a half pitch to thereby
allow all of the balls not introduced into the screw groove 122 of
the nut 101 but left in the guide portion 120a between the guide
surface 120 of the ball insertion jig 104 and the tapered step
portion 121 of the provisional shaft 103 to climb over the tapered
step portion 121, so that the balls are pushed up into the screw
groove 122 of the nut 101 and are held on the provisional shaft 103
and on the BCD of the screw groove 122 of the nut 101.
[0170] After then, in case where a nut positioning cylinder 133 is
pulled back, due to a tension spring 116 mounted on the floating
mechanism 170, the nut 101 is moved from the provisional shaft 103
to the screw shaft fitting position thereof, the provisional shaft
103 and screw shaft 102 are rotated counterclockwise by the drive
motor 111 with a slight tensile force given thereto by the tension
spring 116 to match the nut 101 and screw shaft 102 to each other
in the screw groove phase, thereby being able to start the fit
between the nut 101 and screw shaft 103.
[0171] By the way, the screw shaft 102 and nut 101 can also be
fitted with each other in the following manner: that is, the nut
101 is moved to the fitting position by the tension spring 116 in a
state where the nut 101 and screw shaft 102 are matched in phase to
each other using a sensor (not shown) or the like and, after then,
the screw shaft 101 is rotated counterclockwise by the drive motor
111. Also, in case where the screw shaft 102 and nut 101 are
matched to each other in phase using a clutch (not shown) and the
fitting between them starts, the nut 101 and screw shaft 102 can be
fitted with each other only by a tensile force given by the tension
spring 116 while cutting off a rotation force given by the drive
motor 111.
[0172] In case where the fitting between the nut 101 and screw
shaft 102 is completed, the ball screw apparatus is assembled.
After then, the screw shaft right end support part 108 and ball
screw apparatus are moved together to the right against the
energizing force of the compression spring 115 to thereby remove
the ball screw apparatus from the assembling apparatus, which
completes the assembling operation of the ball screw apparatus.
[0173] By the way, the invention is not limited to the
above-mentioned embodiment but various proper changes are possible
without departing from the gist of the invention.
[0174] For example, in the above-illustrated embodiment, as the
circulating part, there is used a circulating tube. However, the
invention can also be applied to a ball screw apparatus of a
circulating piece type in which the phase of a circulating piece
varies in every circulating circuit. That is, by clamping the nut,
which is fixed in the upward and downward directions, so as to be
rotatable, the phase of the ball exit portion 123 can be matched to
the highest position of the circulating piece, which makes it
possible to assemble the ball screw apparatus of a circulating
piece type.
[0175] Also, in case where the nut 101, ball insertion jig 104 and
ball push-out rod 105 are all structured so as to be rotatable with
respect to the provisional shaft 103, when the provisional shaft
103 is shifted to the left side, the balls are allowed to roll down
into the screw groove 122 of the nut 101 due to their own weights
without pushing up the balls into the screw groove 122 in the
tapered step portion 121, which can reduce the loads to be applied
to the balls.
[0176] Further, in the above-illustrated embodiment, the assembling
apparatus is structured in such a manner that a ball screw
apparatus is assembled while the provisional shaft 103 is disposed
horizontally. However, according to the present assembling
apparatus, the ball screw apparatus can also be assembled even in
case where the inclination angle of the whole of the assembling
apparatus is set freely. For example, in case where the whole of
the assembling apparatus is inclined at such an angle as to be able
to dispose the ball insertion jig 104 at a position higher than the
nut 101 to thereby omit the horizontal portion of the ball
insertion portion 126, insertion of the balls due to their own
weights is possible and thus the ball push-out rod 105 can be
omitted, which makes it possible to reduce the number of parts. In
this case, preferably, as a part which can play the role of a cover
for the ball exit portion 123 when the provisional shaft 103 is
shifted to the left, there may be disposed a shutter
separately.
[0177] Further, in the above-illustrated embodiment, to allow all
of the balls left in the guide portion 120a to climb over the
tapered step portion 121, the provisional shaft 103 is shifted to
the left using the repelling force of the compression spring 115.
However, according to the assembling method of the invention,
instead of this structure, there may also be employed a structure
in which a drive unit including the provisional shaft 103 is fixed
and the ball insertion jig 104 is moved together with the nut 101
to the screw shaft 102 side by a half pitch.
[0178] In this case, the ball push-out rod 105 may be structured
such that it can be moved by a half pitch together with the ball
insertion jig 104. Since the drive unit including the provisional
shaft 103 is fixed, the compression spring 115 need only to support
the screw shaft 102, which can simplify the structure of the whole
of the assembling apparatus. According to the present method, when
there is employed a structure in which the inclination angle of the
whole of the above-described assembling apparatus is set freely, in
case where these two structures are used in combination, there is
eliminated the load to be applied to the compression spring 115,
which can reduce the force that is necessary to make the balls
climb over the tapered step portion 121.
[0179] Further, in the above-illustrated embodiment, the
provisional shaft 103 is rotated using the drive motor 111.
However, a drive motor may be installed on the right end side of
the screw shaft 102 and a rotational force may be applied to the
screw shaft 102 from the drive motor; that is, in this case as
well, a similar ball introduction operation to the
above-illustrated embodiment can be carried out. Also, the
rotational force may also be applied not using the center support
of the right end portion of the screw shaft 102 but using a rotary
chuck.
[0180] And, in the above-illustrated embodiment, the assembling
operation is executed in a state where the provisional shaft 103
and screw shaft 102 are connected to each other. However, after the
provisional shaft 103 is supported or chucked separately, the balls
may be introduced into the nut 101 and, after such introduction of
the balls, the nut 101 and screw shaft 102 may be fitted with each
other. Also, instead of using the cylinder for positioning the
respective support portions, a motor or the like may be used to
position the respective support portions a multi-point positioning
manner. This can also facilitate the automated execution of the
assembling steps.
[0181] Also, as shown in FIG. 15A, the entire outer peripheral
surface of the provisional shaft 103 including the tapered step
portion 121 may also be coated with an elastic member 103c, or, as
an example of the elastic member 103c, urethane rubber or the like
may be shrinkage fitted with or bonded to the entire outer
peripheral surface of the provisional surface 103. In this case,
when the provisional shaft 103 is rotated to thereby introduce the
balls, a frictional force can be applied to the balls and thus the
balls can be made difficult to slip. This can enhance the
introduction efficiency of the balls to the nut 101 side. By the
way, alternatively, an elastic seal member such as an O ring may be
buried in the outer peripheral surface of the provisional shaft 103
in the peripheral direction or in the axial direction. In this case
as well, there can be obtained a similar operation effect.
[0182] Further, as shown in FIG. 15B, an elastic member 103c may
also be spirally coated on or buried in the outer peripheral
surface of the provisional shaft 103 including the tapered step
portion 121. In this case as well, the balls can be introduced into
the nut 101 with high efficiency. Of course, the pitch, lead,
projection amount, width, winding direction and the like of the
elastic member 103c may be set arbitrarily. Also, similarly, the
provisional shaft center support member 107 and the provisional
shaft center support portion of the screw shaft right end support
part 108 may be coated with the elastic member 103c. In this case,
mutual slippage between the screw shaft 102 and provisional shaft
103 can be restricted.
[0183] As can be seen clearly from the foregoing description,
according to a ball given quantity supply apparatus structured in
accordance with the invention, a given quantity of balls can be
always supplied positively and quickly even when supplying a given
quantity of balls which are often covered with oil having a
relatively high coefficient of viscosity such as anticorrosive oil
for supply to a bearing, a ball screw and a linear guide.
[0184] Further, as can be seen clearly from the foregoing
description, according to the invention, since a given number of
balls can be introduced smoothly into the nut with the circulating
part assembled to the nut, the operation efficiency can be
enhanced. Also, because the nut is made eccentric to the
provisional shaft when the balls are introduced into the nut, the
balls can be introduced successively while preventing the balls
from moving too early within the circulation passage. Further, in
case where the elastic member is applied to, buried in, shrinkage
fitted with, or bonded to the outer peripheral surface of the
provisional shaft including the above-mentioned tapered step
portion, the introduction efficiency of the balls into the nut can
be enhanced.
* * * * *