Spatial mechanism for precise rectilinear displacement application on a multipurpose machine-tool.
Dimache, Ionut ; Craciunoiu, Stefan ; Nita, Raluca 等
1. INTRODUCTION
The slide-guide assembly (Sandu et al., 1967) is a machine part
typical for machine-tools construction, highly important in the
assurance of dimensional and form precision for the surfaces machined on
them. The great and continuously increasing number of trajectory
generating machines, comprising the industrial robots and machine-tools,
as a result of multiple cutting methods and connective, lead naturally
to a great variety of guide types, constructive forms and adjusting
methods for them, materials used, computing procedures, manufacturing,
lubricating and maintaining methods.
The attainment of generator curves (Sandu, 2008) in surface
generating process on machine-tools is deployed in two ways:
materialization through tool's cutting edge or by kinematics approach. In kinematical terms, the generator is realised by tool's
cutting edge also, but the generator is the tool's movement
trajectory itself. But these trajectories have a wide range of forms and
their control is one of the most difficult surface generating issues.
To remove those difficulties, mechanisms used on machine-tools
(Botez, 1961) are inferior kinematical joints, translational or
rotational, made from slide-guide and shaft-bearing elements,
respectively.
It is known as fact that the machine-tools retirement, their draw
from manufacturing flow is provoked by precision loss due to normal or
premature slides wear, and the topical industrial robots have an
anthropomorphic structure, using shaft-bearing joints instead of
slide-guide.
2. MULTIPURPOSE MACHINE-TOOL
Various precise rectilinear displacement accomplishment ways for a
mobile element are known, the simplest are linear translation guides,
found especially on machine-tools. The spatial mechanism proposed in
this paper assures the precise rectilinear displacement because
it's made only by levers with rotation joints. The mechanism
assures the kinematical precision, sealing conditions and reduced
friction forces in hard environmental conditions--abrasive dust, shocks,
reduced lubrication and maintenance--unlike the translation guides
classical solutions, which cannot give the precise displacement and low,
constant maintaining of friction forces on the entire displacement
domain. The spatial mechanism for precise rectilinear displacement is
integrated on a NC multipurpose machine-tool for performing special
multiple machining applications.
The NC multipurpose machine-tool (***, 2007) is constituted by the
bed frame A, composed from vertical longerons (beams) 1, 2 and
horizontal superior longeron 3. The cross girders (beams) 4, 5 are
gliding between longerons 1, 2 and are driven by two motors each, 6 and
7, respectively 8 and 9, one NC and one follower. Although there are
four motors, two axes are taken into consideration on Z-Z direction, one
for upper cross girder 4 and one for lower cross girder 5. Those axes
can be controlled independently or simultaneous with realizing and
maintaining a preload. Two electro spindles are positioned on a Z-Z axis
crossing middle of girders 4, 5 each on a girder for tools and/or
devices to be mounted on.
Two cross girders12 and 13 are fixed in middle of cross girders 4,
5. Slides 16 and 17 are gliding on them, due to motors 14, 15 and
nut-screw system 18, along to X-X axis. Two more slides are mounted on
16, 17, with cross-glide possibility, along Y-Y axis.
For an external cylindrical turning, as shown in fig. 1, the work
piece 21 is fixed between girders 4 and 5, actually between electro
spindles 10 and 11, through the universal chuck 22 and an a priori known
back centre not shown in figure, which has a transmitted rotation on Z-Z
axis.
[FIGURE 1 OMITTED]
On any of slides 19 or 20 a turning tool is fixed on a tool holder.
On the opposing side a rolling-device support B is mounted for load
compensation of cutting force, composed from two rollers and
roller-holder frame which can be adjusted up-down by a cursor. After the
rollers are locked on work piece, the frame can be bar-locked.
3. ORIGINAL SOLUTION FOR SUBSTITUTING THE SLIDE-GUIDE WITH
SHAFT-BEARING JOINT
From the presentation of the multipurpose machine tools results
that for actuating the Z-Z axes two engines 6, 7 are necessary for
drop-sledge and two engines 8, 9 for actuating the inferior slide. This
solution presents several disadvantages:
--either slide has two actuating engines, one of them is with
numerical command and the other is for following.
--the cross rail 4 for the superior slide and the 5 for the
inferior slide filled large space in the x axes lengthwise from the
machine jig, which is unjustified because the axes 10 and 11 are always
staying on X axes.
--the structure is over measure and it has an unjustified
supplementary weight for its utilization, for example the utilization of
an only slide on the Z axes, which could need a supplementary space as
in the superior side so as in the underside of the machine.
To throw-away these shortcomings a solution (***, 2002) in which
joint-slide guide is replaced by many shaft-bearing joints is proposed.
Fig. 2 shows for comparison the spindle-bearing joint constructive
solution for the superior and inferior slides, with the objective of
keeping the same vertical dimension.
In addition to removing the above-mentioned disadvantages, the
proposed solution has the advantage that aside of Z axis, along the X
axis, more space will be cleared due to shortening of the cross rails 4
and 5, space in which there can be set up handling systems for parts and
tools. Another possibility to get an exact or approximate rectilinear
motion is achieved by guiding mechanism consisting of levers and
rotation joints.
For these mechanisms the rectilinear trajectory of the led element
is not carried out by special rectilinear guides, but by choosing the
appropriate structure of the mechanism and the length of its elements.
The main advantage of these mechanisms is that the manufacturing
requirements, less demanding than those imposed by the translation
guides, allow to realize simpler, better sealing, in constructive,
efficient and safe terms for the rotation joints, also exhibiting much
smaller moving masses than those of the mechanisms with rectilinear
translation guides.
Shaft-bearing solution description: For the proposed solution, the
girders will be diminished to a dimension which correspond to a 1/3 of
the initial dimension and will form a frame with square section, on
which shackles will be executed. On the upper girder shackles
symmetrical to the column will be also mounted.
The link between upper cross girder and column is made by two
levers articulated with three bolts for each pair of shackles. This way
a translation movement along the Z axis will be realized with a driving
screw-nut mechanism on each joint. When applying this solution some
advantages are obtained as follows:
* ensuring the driven element displacement on a rigorous
rectilinear path defined by the intersection line of the mobility planes
of the jointed arms,
* ensuring optimal sealing and lubrication by usage of rotation
joints only,
* achieving a high stiffness due to the use of a spatial structure,
* the possibility of full eliminating of clearances by the right
choose of constructive solution for rotation joints of the articulated
levers,
* the possibility of getting a complete mechanism equilibration for
the mobile element's horizontal displacement.
[FIGURE 2 OMITTED]
4. CONCLUSIONS
The original solution presented in this article is a mechanism for
the precise rectilinear displacement formed only by levers, articulated
by rotation joints, mechanism that ensures the kinematical precision,
and also the precision conditions for safe sealing and reduced friction
forces in hard working conditions (abrasive dust, beats, reduce
lubrication and maintenance), on the entire moving range.
The device for the precise rectilinear displacement is a particular
case of Stewart table, formed by two pairs of articulated arms with
mobility in concurrent planes, the pairs being cinematically coupled
through rotation joints to a fixed element and a mobile element. The
last one has a precise rectilinear displacement along the intersection
line between the two concurrent planes in which the pairs of articulated
arms are moving.
5. REFERENCES
Botez, E. (1961). Cinematica masinilor-unelte (Kinematics of
machine tools), Ed. tehnica, Bucuresti,
Sandu Gh.; Moraru V.; Minciu C. (1967). Ghidajele masinilorunelte
(Guides machine tools), Ed. Tehnica, Bucuresti,
Sandu I. Gh. (2008). Generarea suprafefelor: tratat (Generating
Surface: Treaty), Ed. Acad. Romane, ISBN 978-973-27-1730-1, Bucuresti
***(2002). SC ICTCM SA, Mecanism pentru deplasare rectilinie
precisa (Mechanism for precise linear motion), Cerere pentru brevet de
inventie A/00894/2002, Bucuresti,
***(2007) SC ICTCM SA, Masina multifuncfionala CNC pentru
prelucrari prin strunjire, frezare, gaurire, alezare, mortezare,
danturare si rectificare plana, cilindrica exterioara si interioara si
helicoidala(Multifunctional CNC machine for machining by turning,
milling, drilling, boring, mortezare, grinding flat, cylindrical outside
and inside) Contract: INOVARE 45/2007, Bucuresti
