Machine tools abstract
A method and a device for hand-operated machine tools, particularly
for hammer drills, for optimal cutting of different substrates by
energy adaptation, wherein the machine tool, when turned on, is
operated initially--preferably in a pre-selectable manner--in a
first operating state (I) with reduced power consumption at reduced
nominal voltage (e.g., 170 V). After a predetermined time period
of 5 seconds, for example, a second operating state (II) with increased
power consumption at full nominal voltage of, for example, 230 V,
is switched to automatically. In the first operating state with
reduced power consumption, the single-blow energy is reduced and/or
the hammer rate and rotational speed are decreased. In particular,
such a method and device ensures that cutting is carried out without
damage in the case of hollow block material and a precise tap-drilling
is ensured in the case of solid material. In the second operating
state with increased power consumption, the single-blow energy and
the frequency and rotational speed are adjusted to an increased
desired value ensuring fast setting of a bore hole.
Machine tools claims
What is claimed is:
1. A method for automatically presetting a hand-operated machine
tool (M), particularly a hammer drill, that can be operated in different
operating states, wherein the machine (M) is initially switched
to a first operating state (I) with reduced power consumption when
turned on and, after a short predetermined time, is switched to
a second operating state (II) with increased power consumption.
2. The method of claim 1 wherein the machine (M) is switched from
the first operating state (I) to the second operating state (II)
after a time period of 2 to 20 seconds.
3. The method of claim 2 wherein the time period is approximately
5 seconds.
4. The method of claim 1 wherein the machine (M) is supplied with
a voltage of 140 to 200 V, particularly 170 V, in the first operating
state (I).
5. The method of claim 4 wherein the machine (M) is operated in
the first operating state (I) with at least one of reduced rotational
speed, reduced hammer rate, and reduced single-blow energy in comparison
with the second operating state (II).
6. The method of claim 1 wherein the machine (M) is supplied with
a nominal voltage between 210V to 240 V, in the second operating
state (II).
7. The method of claim 6 wherein the machine (M) is operated in
the second operating state (II) corresponding to the increased supply
voltage at at least one a higher rotational speed, higher hammer
rate, and substantially increased single-blow energy.
8. The method of claim 1 wherein the automatic preadjustment can
be inhibited.
9. A hand-operated machine tool (M), particularly hammer drill,
comprising a device for automatically adjusting a first operating
state (I) with reduced power consumption when the machine is turned
on and for switching over in a time-dependent manner to a second
operating state (II) with increased power consumption.
10. The machine tool of claim 9 comprisng a device that compulsorily
blocks the second operating state (II) for a predetermined period
of several seconds when the machine is turned on.
11. The machine tool of claim 9 comprising a timer circuit which
can be initialized by an ON/OFF hand switch (11) and which sets
a thyristor to reduced output voltage during the first operating
state (1) and, after a predetermined time period of several seconds,
causes the nominal voltage to be switched through to the motor of
the machine.
12. The machine tool of claim 9 wherein the automatically adjusting
device is installed in an ON/OFF switch of the machine (M).
13. The machine tool of claim 9 comprising a selection device
at the machine (M) for presetting the automatic adjustment.
14. The machine tool according to claim 13 wherein the selection
device is a mechanical selection device associated with an ON/OFF
hand switch of the machine (M).
15. The machine tool of claim 14 wherein the selection device
is a selector lever that can be swiveled between two catch positions
defined in the housing of the ON/OFF hand switch (11) by grooves
of different lengths.
16. The method of claim 1 wherein the machine (M) is supplied
with a line voltage of 230 V, in the second operating state (II).
Machine tools description
FIELD OF THE INVENTION
[0001] The invention is directed to a method and device for hand-operated
machine tools for optimized cutting of different substrates. In
particular, the invention is directed to a method for automatically
presetting a hand-operated machine tool, particularly a hammer drill,
which can be operated in different operating states, wherein the
machine is initially switched to a first operating state with reduced
power consumption when turned on and, after a short predetermined
time, is switched to a second operating state with increased power
consumption. Moreover, the invention is directed to a hand-operated
machine tool, particularly hammer drill, wherein the device automatically
adjusts to a first operating state with reduced power consumption
when the machine is turned on and switches over in a time-dependent
manner to a second operating state with increased power consumption
BACKGROUND DESCRIPTION
[0002] Machine tools of the type mentioned above, that is, hammer
drills in particular, are used to cut a wide variety of substrates.
In a simple embodiment, these devices, after being turned on, are
generally operated in one individual operating mode with constant
pre-settable power consumption. In addition, such devices can be
outfitted with an adjusting element, e.g., a potentiometer, which
is generally integrated in the handle, so that the user can adapt
the device for cutting different substrates by changing the rotational
speed and/or the hammer rate and single-hammer-blow energy.
[0003] Before cutting, however, it is often impossible to see from
the outside what type of material the substrate to be cut is made
of. With excessive rotational speeds or excessive single-blow energy,
the problem arises, particularly in certain materials such as hollow
blocks, as they are called, that the energy provided is too high
and can result in unwanted damage to the substrate, for example,
by collapsing intermediate webs, so that holding elements such as
dowels can no longer be anchored with sufficient strength. This
applies particularly to hammer drills outfitted with the adjusting
members mentioned above, for example when the user mistakenly sets
an excessively high motor speed when switching on the device.
[0004] EP 0 734 116 A2 describes a method and a circuit arrangement
for operation of an electric motor in an electric hand tool. In
a first operating phase, the motor can be operated at a first, variably
pre-adjustable speed until a preset limiting torque is reached.
In a subsequent operating phase, the motor is operated through torque
pauses to a periodically interrupted final torque or after-torque.
Better work results are achieved in this way, especially when screwing
in screws.
SUMMARY OF THE INVENTION
[0005] It is the object of the invention to improve a machine tool
of the type mentioned above such that with different, initially
unknown materials to be cut, an optimal holding coefficient is always
achieved in the substrate without risk of mishandling of the device
resulting in an unavoidable worsening of the holding coefficients.
[0006] In accordance with the invention, there is provided a method
for automatically presetting a hand-operated machine tool, especially
a hammer drill, which can be operated in different operating states,
wherein the machine is initially switched to a first operating state
with reduced power consumption when turned on and, after a short
predetermined time period, is switched to a second operating state
with increased power consumption.
[0007] The method according to the invention can be applied particularly
in a hand-operated hammer drill by which, for example, fastener
bore holes et al. are to be set in a hollow block material or solid
material. When the machine is turned on, the supplied supply voltage
or line voltage of, e.g., 230 V nominal value is reduced to an appreciably
lower value, e.g., 140 to 200 V, particularly 170 V, by means of,
e.g., a thyristor element triggered by a timing logical element.
The hammer drill is accordingly operated in this first operating
state with low single-blow energy and/or lower hammer rate and/or
lower rotational speed. In particular, the collapsing of intermediate
webs in hollow block materials can be avoided in this way, so that
a substantially better holding coefficient is achieved, on the whole,
for dowels or other fastening elements.
[0008] According to the invention, the hammer drill is initially
operated for a determined period of, e.g., 5 seconds in a first
operating state, wherein a setting depth of several times 10 mm,
for example, 80 mm, is achieved during this first operating phase,
for instance when cutting hollow block bricks, so that a sufficient
guiding of the drill is ensured. In an advantageous constructional
variant, the first time period for the first operating state is
variably adjustable. However, for most applications, a fixed preset
time period is desirable; accordingly, a presetting to 2 to 20 second,
particularly 5 seconds, is to be provided, for example. The subsequent
automatic upshifting to high single-blow energy ensures a desired
quick setting of a hole intended for holding elements. The guiding
of the drill, which is now reliable, prevents unwanted bursting
of intermediate webs in the hollow block material.
[0009] It is advantageous to switch the hammer drill initially
and compulsorily into the first operating state every time it is
turned on. This prevents the user from operating the hammer drill
incorrectly and with full power consumption immediately. A possibly
unintentional altering of the operating performance of the hammer
drill is reliably prevented.
[0010] After the predetermined time period has elapsed, the reduction
of the nominal voltage is suspended; the machine switches automatically
until the nominal voltage is switched down, for example, to a line
voltage of 230 V. At increased power consumption in the second operating
state, the device is then operated at a predetermined higher rotational
speed and/or at a higher hammer rate or higher single-blow energy.
[0011] With the method according to the invention, advantages are
also gained in cutting solid material because a precise tap-drilling
of the material is ensured during the first operating state and
the drill is prevented from accidentally sliding off the location
to be drilled.
[0012] A hand-operated machine tool, especially a hammer drill,
is characterized according to the invention by a device for automatically
adjusting a first operating state with reduced power consumption
when the machine is turned on and for switching over in a time-dependent
manner to a second operating state with increased power consumption.
Switching over from the first operating state to the second operating
state is effected compulsorily and without the direct influence
of the user of the device.
[0013] In a particularly advantageous manner, the timer circuit
which is provided for time-dependent switching over and which has
a power switching element, for example, a thyristor, as an integrated
circuit or as a hybrid circuit is integrated directly in the handle
or in a push switch in the handle of the machine.
[0014] Other advantageous constructions and further developments
of the inventive idea are explained more fully in the following
description.
BRIEF DESCRIPTION OF THE DRAWINGS
[0015] The invention and advantageous details thereof are described
more fully in the following description with reference to the following
drawings by way of example.
[0016] FIG. 1 shows a block diagram illustrating a method in accordance
with the invention;
[0017] FIG. 2 shows a time graph illustrating different operating
states;
[0018] FIG. 3 shows a schematic sectional view of a commercially
available hammer drill which is outfitted with a switchover device
according to the invention;
[0019] FIG. 4 shows a schematic perspective view of a hand switch
which is actuated by finger pressure and is swivelably articulated
in the handle of a machine tool and has a selector lever for different
press-in depths for selective operation preset; and
[0020] FIG. 5 with parts 5a, 5b and 5c, shows a schematic top
view of the hand switch with associated selector lever of FIG. 4
illustrating its operation.
DETAILED DESCRIPTION OF THE INVENTION
[0021] FIG. 1 illustrates the basic sequence of the method according
to the invention. A nominal voltage, for example, a line voltage
of 230 V, is supplied to the machine via a line cord N, referred
to in FIG. 3. A device 1 according to the invention, for initial,
brief reduction of the nominal voltage of 230 V to, e.g., 170 V
is contained in the handle of the machine with an ON/OFF hand switch
11.
[0022] As is seen from FIG. 1 the motor 2 of the hammer drill
M, of FIG. 3 is initially provided with the reduced voltage of,
e.g., 170 V after being turned on by actuating the ON/OFF hand switch
11 so that a first operating state 1 shown in FIG. 2 with reduced
power consumption is preset and adjusted. The reduction of the supply
voltage is advantageously carried out by means of a controllable
power semiconductor switch, particularly a thyristor, which is driven
by an electronic timer. At the reduced voltage of 170 V in the first
operating state, the hammer drill M is accordingly operated in particular
with low single-blow energy at low speed and low hammer rate.
[0023] After a predetermined time period of several seconds, for
example, 2 to 20 seconds, preferably 5 seconds, the device 1 for
the time preset and switchover causes an upshifting to the normal
rated voltage of, e.g., 230 V. The reduction in the nominal voltage
to 170 V, which is adjusted initially when turning on, is canceled
and the machine M is switched over to the second operating state
II, shown in FIG. 2 with increased power consumption. The hammer
drill M now operates with a greater single-blow energy, higher rotational
speed and/or increased hammer rate.
[0024] The processes described above are illustrated in a time
chart shown in FIG. 2. In a first operating state I, that is, when
the hand switch 11 is actuated, the supply voltage V is initially
switched to a reduced nominal value of, e.g., 170 V. After a predetermined
time period Z of 5 seconds, for example, this reduced supply voltage
is canceled and the second operating state II is switched to, that
is, in general, a switching over to a line voltage of 230 V is effected.
In FIG. 2 a voltage changeover is provided after a time period
of 5 seconds for the first operating state I in the form of a step
function. The hammer drill M is accordingly switched over immediately
to the nominal voltage, particularly the line voltage of 230 V,
when a period of 5 seconds has been exceeded. A continuous switching
over with a continuous transition from the first operating state
to the second operating state can likewise be provided, wherein
the transition time is advantageously pre-adjusted to several seconds,
for example, 2 to 4 seconds. As can also be seen from the horizontal
curve shape in FIG. 2 the level of applied supply voltage is constant
during the first operating state I and during the second operating
state II. It can also be seen from the curve shape in FIG. 2 that
the hammer drill M remains "infinitely long" in the second
operating state II with continued actuation of the hand switch 11.
The machine M is turned off only when the hand switch 11 has been
released. When the hand switch 11 is actuated again, the reduced
supply voltage of 170 V is again supplied initially. Accordingly,
without some other kind of possible switchover, it is impossible
for the user of the device to switch on the second operating state
II immediately and directly by actuating the hand switch 11.
[0025] The hammer drill M, which is shown in FIG. 3 has a hammering
mechanism (not shown) which propels the drill 4 in translational
motion and which is driven by the motor via a safety clutch 5 which
is not relevant in the connection with the invention. As is shown,
the switchover device 1 according to the invention can be fitted
directly in the handle or integrated therein.
[0026] By means of the invention, a commercially available hammer
drill can be modified--also retrofitted--in such a way that cutting
can be adapted to different substrate materials in every case. In
the first operating state I with reduced power consumption which
is adjusted automatically after turning on, a sufficiently deep
setting hole is achieved on the one hand in relatively unstable
hollow block materials so as to ensure good guiding of the drill
4. Damage to the material, especially bursting of intermediate webs,
is prevented. On the other hand, in the case of solid material,
a hole to be set is pilot-drilled initially so that the drill 4
is reliably prevented from sliding off. A fast setting of the desired
fastener hole is simultaneously ensured by switching to operating
state II which is carried out after, e.g., 5 seconds.
[0027] According to an advantageous development of the invention,
the machine tool can have a selection device by which a preset can
be selected for the automatic adjustment of the first and, subsequently,
the second operating state. In one setting of the selection device,
the two-stage upshifting of the machine according to the invention
is adjusted, while in the other setting of the selection device,
the operating parameters desired by the user of the device, that
is, the second operating state with increased power consumption,
are immediately available.
[0028] FIGS. 4 and 5 show an embodiment for a selection device
which contains a purely mechanical solution in the illustrated example.
Of course, appropriate purely electrical or electromechanical selection
devices are also possible and would require no special explanation
for the person skilled in the art.
[0029] FIG. 4 shows a view in perspective of the selection device
which is designated generally by 10 and which comprises the combined
action of an ON/OFF hand switch 11 articulated at a swivel pin 12
in the handle-side housing part of the machine M and a swivel lever
15 which is likewise mounted in the handle-side housing part of
the machine M in a bearing block 13 and which is swivelable about
a pivot pin 14. Two catch grooves 17 and 18 having different depths
are formed on the upper side, facing the observer, of the spring-biased
hand switch 11 which is articulated at 12 wherein a guide shoe
or sliding block 16 provided at the swivel lever 15 is oriented
toward the catch grooves 17 and 18 depending on the selected swiveling
position of the swivel lever 15. As can be seen from the individual
positions shown in FIGS. 5a to 5c, the swivel lever 15 and its associated
sliding block 16 are swivelable inside a cutout 19 in the hand switch
11 between two stop positions in a first swiveling direction 20
and second swiveling direction 21. However, this movement is only
possible provided that the spring-biased hand switch 11 is not pressed
by the user of the device, that is, as long as it is not locked
into the grooves. This hand switch position is illustrated in FIG.
4 and in FIG. 5a. The swivel lever 15 is swivelable between the
two catch grooves 17 and 18 with different depths. When the swivel
lever 15 is swiveled into the position illustrated, in FIG. 5a,
by arrow 20 the hand switch 11 can be pressed in farther in the
direction of arrow 22 (compare FIG. 5b) than in the other swivel
position with orientation toward the shallower catch groove 18 (compare
FIG. 5c).
[0030] When the selector lever 15 is in the left-hand position,
that is, in the position oriented to the deep catch groove 17 as
shown in FIG. 5b, the user of the device can fully depress the ON/OFF
hand switch 11 and the preadjusted operating parameters of the machine
tool M corresponding to the second operating state can immediately
take effect. Such positioning can be important for many applications,
particularly with the possibility of selecting chisel operation.
On the other hand, in the swivel position of the selector lever
15 shown in FIG. 5c, the ON/OFF hand switch 11 cannot be pressed
in completely. The positioning shown in FIG. 5 illustrates the selected
automatic adjustment, according to the invention, of the operating
performance of the machine M in which the first operating state
I with reduced power consumption is automatically adjusted initially
and subsequently, in time-dependent manner, the second operating
state II with increased power consumption is switched to. |