Machine tools abstract
The invention effects an increase in the range of continuously
variable tool speed and torque control for machine tools beyond
that conventionally available for operation from single phase alternating
current. Interactive operator control of mechanical speed regulation
is additively coupled to electrical control of direct current motor
drive to reduce or eliminate machine down time needed for performing
a series of varied machine operations.
Machine tools claims
I claim:
1. Drive means for a machine tool supplied with single phase alternating
current, an improvement providing a wide range of continuously variable
cutting tool shaft speeds at high torque, comprising
a) a current rectifier together with a voltage regulator having
a plurality of selective settings,
b) a direct current electric, tool rotation drive motor,
c) power transmission means comprising a driving shaft having operably
mounted thereon a first sheave and a driven shaft having mounted
thereon a second sheave wherein at least one of said first sheave
and said second sheave is a variable pitch diameter sheave,
d) a power transmission belt operably engaged with said first sheave
and said second sheave to transmit rotational motion from said driving
shaft to said driven shaft,
e) belt tensioning means operably biasable by a machine operator
to increase tension and decrease tension in said power transmission
belt to operably vary the pitch diameter of said variable pitch
diameter sheave.
2. The drive means for a machine tool of claim 1 wherein said drive
motor is a permanent magnet motor.
3. The drive means for a machine tool of claim 1 comprising a motor
mounting pivotally disposed so that pivotal biasing thereof increase
or reduces tension in said power transmission belt to operably vary
the pitch diameter of said variable pitch diameter sheave by increasing
or decreasing the distance between said driving shaft and said driven
shaft.
4. The drive means for a machine tool of claim 1 wherein said power
transmission belt is a V-belt.
5. The drive means for a machine tool of claim 1 wherein said variable
pitch diameter sheave is spring biased.
6. The drive means for a machine tool of claim 1 comprising a motor
mounting pivotally disposed so that pivotal biasing thereof increases
or reduces tension in said power transmission belt to operably vary
the pitch diameter of said variable pitch diameter sheave by increasing
or decreasing the distance between said driving shaft and said driven
shaft, and further comprising a lever connected for pivotally rotating
said motor mounting by application of manually applied force thereagainst.
7. The drive means for a machine tool of claim 1 wherein said drive
motor is provided with constant field flux.
8. A method for providing operator interactive operation of a machine
tool powered by single phase alternating electric current in a manner
to increase torque supplied to a cutting tool and decrease tool
speed comprising the steps of:
a) providing a single phase alternating current rectifier together
with a voltage regulator having a plurality of selective settings,
b) providing a direct current, electric tool-rotation drive motor,
c) providing a V-belt engaged with a driving sheave and with a
driven sheave wherein at least one said sheave is a variable pitch
diameter sheave,
d) providing an operator manipulated belt tensioning means for
increasing and decreasing tension in said V-belt, whereby through
increased or decreased tension in said V-belt, the pitch diameter
of said variable pitch diameter sheave is varied, thereby to alter
the rotational speed and the torque supplied by said driven sheave
to a cutting tool and to provide optimum values of torque and rotational
speed to a cutting tool when operator manipulation of said belt
tensioning means is made in conjunction with operator selection
of said selective settings.
9. The method of claim 8 wherein said belt tensioning means operates
to increase or decrease the distance between said driven sheave
and said driving sheave.
Machine tools description
FIELD OF USE
Machine tools are provided with power transmission means in which
the ratio of motor output shaft speed and torque to tool speed and
torque can be changed.
BACKGROUND OF INVENTION
Electrical service furnishes 240 volts single phase alternating
current to virtually all customers of power utilities in the United
States. The relative inexpensiveness and widespread availability
of such service has caused manufacturers to equip their machinery
to utilize such current in power requirements up to about three
horsepower, and also to manufacture products which utilize such
current. The motors most commonly used with alternating current
are characterized by near constant operating speed and low starting
torque when compared to motors which utilize polyphase or direct
current. Where a greater range of speed and torque control is required
than is possible with single phase alternating current motors, motor
driven generators or rectifiers may be used to supply direct current
to a machine drive motor from single phase alternating current service.
The method and means of this invention increases the range of continuously
variable tool speed and torque control from that heretofore available
to operate machine tools from single phase alternating current by
additively coupling interactive machine operator manual control
of mechanical regulation of speed and torque to that of electrical
control using direct current motor drive, to effect reduction or
elimination of machine down time needed for performing a series
of machine operations requiring differing tool speeds and torques.
SUMMARY OF THE INVENTION
Alternating current rectification, pole reversal switching, and
voltage control in conjunction with interactive manual control of
biasing of a variable diameter drive belt sheave provides a capability
to a machine tool furnished with single phase alternating current
to perform a greater range of machining operations than is possible
with conventional machine drives using similar current and of similar
motor ratings, without requiring down-time for changing drive belt
or gear engagement necessary to complete the range of operations.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a right side elevational view, oriented with respect
to a machine operator, of an embodiment of a portion of a drill
press machine tool of this invention;
FIG. 2 is a left side elevational view of the embodiment of FIG.
1;
FIG. 3 is a top plan view of the embodiment of FIG. 1.
DESCRIPTION OF THE INVENTION
Referring to the drawings, FIGS. 1 and 2 shown drill press 10 in
truncated elevational views with base standard deleted for convenience
of illustration. A drill press is selected as an example of one
type of machine tool embodying the method and means of this invention,
with the application of the invention to other kinds of machine
tools being apparent to persons skilled in the art, and such applications
are included in the scope of invention described and claimed.
Post 11 extends vertically from a base standard, not shown, carrying
elevationally adjustable work table 12 clamped thereon, and in addition
carrying horizontally extending cabinet 13 housing the mechanisms
for driving and for elevationally biasing drill chuck 14 and affixed
drill bit 15. Multiply grooved, stepped diameter sheave 16 is fixed
on a shaft, concealed from view, which carries chuck 14. Lever 17
is rotatively biased manually by a machine operator to operable
raise and lower drill bit 15. Power transmission V-belt 18 is engaged
with sheave 16 for rotatively driving chuck 14 and drill bit 15.
Clamp bracket 19 is disposed on the opposite side of post 11 from
that of cabinet 13 being bolted to the cabinet to tightly secure
the assembly on post 11. The foregoing disclosure describes prior
art and comprises no part of this invention.
Bracket 20 is frictionally clamped on post 11 for supporting arm
21. Adjustable, threaded rod 22 is threadedly engaged with the far
reach of arm 22 for carrying control box 25. Within control box
25 are housed a rectifier for single phase alternating current,
preferably a full wave rectifier, a voltage controller, a terminal
reversing switch, and an on-off switch, all concealed from view.
Control box 25 equipped as described can be purchased, for example,
from Minarik Electric Company, Glendale, Calif.
Toggle switch levers 26 27 and dial 28 are shown projecting from
the front of control box 25 for controlling, respectively, voltage,
on-off, and current reversing functions. Electrical lead 30 depending
from control box 25 supplies single phase alternating current to
drill press 10 through control box 25. Electrical lead 31 provides
rectified current from control box 25 to junction box 33 on direct
current motor 35. Motor 35 may be any suitably constructed motor,
a preferred embodiment being a permanent magnet motor as manufactured,
for example, by Leeson Electric Motor Corporation, Grafton, Wisc.
Motor 35 is fixedly mounted on hinge plate 37 for being arcuately
moved together with the hinge plate around hinge connector 38 with
hinge connector being disposed pivotally connecting fixed mounting
plate 39 with hinge plate 37. Bolts 40 secure mounting plate 39
to cabinet 13. Hinge rod 42 is connected to the far reach of plate
37 enabling plate 37 to be manually biased around hinge connector
38 for altering the distance between sheave 16 mounted on cabinet
13 and sheave 50 mounted on motor shaft 36. Rod 42 as shown is is
axially rotative and operably and outwardly movable in ball joint
43 mounted on hinge plate 37 so that handle portion 41 of rod 40
can be disengaged from notches 46 in bar 47 and the rod pushed,
or raised and swung outwardly to increase the length of the lever
arm before being pushed, to rotate hinge plate 37 about hinge connector
38 and lengthen the distance from sheave 16 to sheave 50. Bar 47
is adjustably mounted on the side of cabinet 13 by being engaged
in slotted feet 60 for longitudinal movement to accommodate stretch
in V-belt 18 which occurs from use. Three notches 46 conform to
the positions of handle portion 41 of rod 40 corresponding to engagement
of V-belt 18 in each of the three grooves in stepped diameter sheave
16. Adjusting screw 61 is threaded through tapped lug 62 on cabinet
13 to provide an adjustable stop against which bar 47 abuts under
tension of V-belt 18 urging rod 42 and bar 47 with which handle
portion 41 of rod 42 engages, toward the front of drill press 10.
Variable diameter sheave 50 is fixedly mounted on output shaft
36 of motor 35. Sheave 50 comprises lower flange 53 fixed on shaft
36 and upper flange 54 splined to be axially movable on shaft 36.
Upper flange 54 is downwardly biased by compression spring 55 toward
lower flange 53 with spring 53 disposed with its upper end extremity
abutting head 56 at the top of shaft 36 and with the lower extremity
of the axially extended spiral configuration of the spring contacting
the outer peripheral extremity of upper flange 54 of sheave 50.
Compression in spring 53 acts in opposition to tension in V-belt
18 in changing the pitch diameter of sheave 50 with tension decreasing
the pitch diameter of sheave 50 and spring compression increasing
it. Biasing of rod 40 in a direction which moves hinge plate 37
rearward and away from clamp bracket 19 increases tension in V-belt
18 and forces flange 54 of sheave 50 upward against the urging of
spring 53 thereby decreasing the pitch diameter of sheave 50. In
response to such manual biasing of rod 40 by a machine operator
during drilling operations, the rotational speed of a tool such
as drill bit 15 decreases and torque increases. Many drilling operation
for bit diameters up to approximately one inch are best performed
in steel stock at speeds of from about 50 to 85 revolutions per
minute, with lower speeds being desirable for use with hole cutters.
For use with taps, both lower speeds and repeated reversal of rotational
direction are required. With drill press 10 all operations can
be performed without requiring machine down-time for changing drive
belt 18 on its sheaves. Rather, reduction in rotating speed and
increase in torque beyond that available from motor control alone
is provided by operator biasing of rod 40 in suitable manner, with
tap use being made convenient and fast by use of reversing switch
27 to repeatedly reverse rotational direction of a tap drive. Myriad
other situations in operating a drill press will present themselves
in which one embodiment of invention described enables machining
operations to proceed without requiring repositioning of drive belt
or gears as otherwise would be required.
Adaptation of the disclosed invention to machine tools other than
drill presses will be apparent to persons skilled in the art, such
as, for example, to a milling machine, and such adaptation is included
within the scope of the disclosure and claims of this specification.
Other arrangements for tensioning drive belt 18 will be apparent,
such as, for example, by use of belt tensioning idler sheave or
pulley, which acts respectively, against the outer face or inner
face of V-belt 18 between sheaves 16 an 50 for operably varying
the pitch diameter of sheave 50. Means such as rod 40 for operating
a belt tensioner may be mounted on either side of a machine tool
such as drill press 10 for the convenience of a machine operator. |