[0001] The present invention relates to a motor drive switch that can be used in a motor
control circuit.
[0002] Japanese Laid-Open Patent Publication No.
2-184279 discloses a motor drive switch relating to a peripheral technology.
[0003] As shown in FIG 8A, a motor drive switch 100 disclosed in Japanese Laid-Open Patent
Publication No.
2-184279 is a double-pole switch consisting of a first contact 101 and a second contact 102,
with the first contact 101 and the second contact 102 being interlocked with each
other when a motor is driven.
[0004] The first contact 101 of the motor drive switch 100 is connected to one end (12)
of a motor stator winding 112, and can be switched between a power source P-side terminal
(3) connected to the P side of a power source E and an armature P-side terminal (1)
connected to the P side of an armature 104. The second contact 102 is connected to
the other end (5) of the motor stator winding 112, and can be switched between an
armature P-side terminal (6) and an armature N-side terminal (4) connected to the
N side of an armature 104.
[0005] And, as shown in FIG 8A, when the motor drive switch 100 is switched in a start operation
of the motor, the first contact 101 is switched to the power source P-side terminal
(3), and the second contact 102 is switched to the armature P-side terminal (6). As
a result, the stator winding 112 and the armature 114 are connected in series between
the P terminal and N terminal of the power source E, whereby the motor is started.
[0006] As shown in FIG 8B, when the motor drive switch 100 is switched in a stop operation
of the motor, the first contact 101 is switched to the armature P-side terminal (1),
and the second contact 102 is switched to the armature N-side terminal (4), with the
result that the stator winding 112 and the armature 114 form a closed loop, and the
motor operates like a generator, whereby a brake is applied.
[0007] Between the armature N-side terminal (4) of the second contact 102 and the N terminal
of the armature 114, there is provided a resistor 116 for restricting a brake current.
[0008] In the above motor drive switch 100, the first contact 101 and the second contact
102 are switched substantially simultaneously. Thus, in a case where contact sticking
occurs at the first contact 101 and the second contact 102 due to aging or the like,
it is impossible to determine at which of the positions (1), (3), (4), and (6) such
contact sticking occurs.
[0009] For example, as shown in FIG 8C, contact sticking has occurred at the power source
P-side terminal (3) of the first contact 101 during the motor is operated, and then
motor stop operation is performed on the motor drive switch 100 and the second contact
102 is switched to the armature N-side terminal (4), a large current Im might flow
through the stator winding 112, which causes the stator winding 112 to burn out.
[0010] Thus, there is a need in the art to prevent the stator winding of a motor from being
damaged even when contact sticking of a motor drive switch occurs. Another example
of motor drive switch is disclosed in
US-A-5449992.
[0011] One construction for a motor drive switch includes a first contact which is connected
to one end of a stator winding of a motor and which can be switched between a power
source P-side terminal connected to a P side of a power source and an armature P-side
terminal connected to a P side of an armature. The motor drive switch further includes
a second contact which is connected to the other end of the stator winding and which
can be switched between the armature P-side terminal and an armature N-side terminal
connected to an N side of the armature. The motor drive switch used in a motor control
circuit is configured such that the first contact is switched to the power source
P-side terminal, and that the second contact is switched to the armature P-side terminal
by a start operation of the motor, whereby the stator winding and the armature are
connected in series between the P side and the N side of the power source thereby
to start the motor. The motor drive switch is further configured such that by a stop
operation of the motor, the first contact is switched to the armature P-side terminal
and the second contact is switched to the armature N-side terminal, with the result
that the stator winding and the armature form a closed loop to brake the motor. In
the start operation of the motor, the switching of the first contact to the power
source P-side terminal is configured to be effected earlier than the switching of
the second contact to the armature P-side terminal, and in the stop operation of the
motor, the switching of the second contact to the armature N-side terminal is configured
to be effected earlier than the switching of the first contact to the armature P-side
terminal.
[0012] According to this construction, in the start operation of the motor, the switching
of the first contact to the power source P-side terminal is configured to be effected
earlier than the switching of the second contact to the armature P-side terminal.
Thus, an electric current flows through the stator winding and the armature of the
motor at the time when the second contact is switched to the armature P-side terminal.
Thus, if contact sticking is to be occurred with the passage of time, it occurs between
the second contact and the armature P-side terminal.
[0013] If contact sticking occurs at the armature P-side terminal of the second terminal
and then the stop operation is performed on the motor drive switch and the first contact
is switched to the armature P-side terminal, no electric current flows through the
stator winding of the motor. That is, no abnormal current flows through the stator
winding of the motor due to contact sticking.
[0014] Further, in the stop operation of the motor, configuration is made such that the
switching of the second contact to the armature N-side terminal is effected earlier
than the switching of the first contact to the armature P-side terminal. Thus, an
electric current flows through the stator winding and the armature of the motor at
the time when the first contact is switched to the armature P-side terminal. Thus,
if contact sticking is to be occurred with the passage of time occurs, it occurs between
the first contact and the armature P-side terminal.
[0015] If contact sticking occurs at the armature P-side terminal of the first contact and
then start operation is performed on the motor drive switch and the second contact
is switched to the armature P-side terminal, the motor does not start and no electric
current flows through the stator winding of the motor. That is, no abnormal current
flows through the stator winding of the motor due to contact sticking.
[0016] According to another construction, there is provided a trigger that can perform the
start operation of the motor by sliding of the trigger from a stop position to a start
position and perform the stop operation of the motor by returning of the trigger from
the start position to the stop position. The trigger has a first protrusion and a
second protrusion that can respectively press the first contact and the second contact
during the sliding, and each of the first contact and the second contact is formed
in a scale-like arcuate configuration whose center is supported by a fulcrum. Further,
each of the first contact and the second contact tilts around the fulcrum when each
contact is pressed by the first protrusion and the second protrusion respectively,
thereby effecting switching of the contacts. And the first protrusion and the second
protrusion are arranged so as to be offset in the sliding direction, whereby there
is a difference in switching time between the first contact and the second contact.
[0017] According to another construction, there is provided a trigger that can perform the
start operation of the motor by sliding of the trigger from a stop position to a start
position and perform the stop operation of the trigger by returning of the trigger
from the start position to the stop position. The trigger has a first protrusion and
a second protrusion that respectively presses the first contact and the second contact
during the sliding, and each of the first contact and the second contact is formed
in a scale-like arcuate configuration whose center is supported by a fulcrum. Further,
each of the first contact and the second contact tilts around the fulcrum when each
contact is pressed by the first protrusion or the second protrusion, thereby effecting
switching of the contacts. And bending positions of the first contact and the second
contact are offset in the sliding direction, whereby there is a difference in switching
time between the first contact and the second contact.
[0018] According to another construction, there is provided a trigger that can perform the
start operation of the trigger by sliding of the trigger from a stop position to a
start position and perform the stop operation of the trigger by returning of the trigger
from the start position to the stop position. Each of the first contact and the second
contact is accommodated in a case respectively, and operating pins protruding from
the case are pressed or depressed to effect switching of the contacts. The trigger
has a first pressing surface and a second pressing surface which are configured to
press an operating pin for the first contact and an operating pin for the second contact
respectively and which are formed to be offset from each other in the sliding direction.
[0019] According to the above, even if contact sticking occurs in the motor drive switch,
no abnormal current flows through the stator winding of the motor. Thus, there is
no possibility of the stator winding being damaged, which reduces the burdens of servicing.
[0020] Additional obj ects, features, and advantages, of the present invention will be readily
understood after reading the following detailed description together with the claims
and the accompanying drawings, in which:
FIG 1A is a motor control circuit diagram showing a state in which a motor drive switch
is switched to a stop side according to an example of the present invention; FIG 1B
is a motor control circuit diagram showing the circuit during the switching from the
stop side to a start side; and FIG 1C is a motor control circuit diagram showing a
state in which the motor drive switch is switched to the start side;
FIG 2A is a motor control circuit diagram showing a state in which the motor drive
switch is switched to the start side; FIG 2B is a motor control circuit diagram showing
the circuit during the switching from the start side to the stop side; and FIG 2C
is a motor control circuit diagram showing a state in which the motor drive switch
is switched to the stop side;
FIG 3A and FIG 3B are motor control circuit diagrams showing a state in which contact
sticking occurs at a second contact of the motor drive switch;
FIG 4A and FIG 4B are motor control circuit diagrams showing a state in which contact
sticking occurs at a first contact of the motor drive switch;
FIG 5A and FIG 5B are schematic longitudinal sectional views showing the operation
of the motor drive switch; FIG 5C is a schematic cross-sectional view of the same;
and FIG 5D is a bottom view of a trigger of the motor drive switch;
FIG 6A is a side view of a first contact of a motor drive switch according to another
example; FIG 6B is a side view of a second contact of the same; FIG 6C and FIG 6D
are longitudinal sectional views showing the operational timing of the first contact
and the second contact; and FIG 6E is a bottom view of a trigger of the motor drive
switch;
FIG 7A is a side view of a trigger of a motor drive switch according to another example;
FIG 7B is a bottom view of the trigger; FIG 7C is a side view of the motor drive switch
before switching; FIG 7D is a rear view of FIG 7C; and FIG 7E is a side view of the
motor drive switch after switching; and
FIG 8A is a motor control circuit diagram showing a state in which a motor drive switch
is switched to a start side in a prior art; FIG 8B is a motor control circuit diagram
showing a state in which the motor drive switch is switched to a stop side; and FIG
8C is a motor control circuit diagram showing a state in which contact sticking occurs
at a first contact and a second contact.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0021] Each of the additional features and teachings disclosed above and below may be utilized
separately or in conjunction with other features and teachings to provide improved
motor drive switch. Representative examples of the present teaching, which examples
utilize many of these additional features and teachings both separately and in conjunction
with one another, will now be described in detail with reference to the attached drawings.
This detailed description is merely intended to teach a person of skill in the art
further details for practicing preferred aspects of the present teachings and is not
intended to limit the scope of the invention. Only the claims define the scope of
the claimed invention. Therefore, combinations of features and steps disclosed in
the following detailed description may not be necessary to practice the invention
in the broadest sense, and are instead taught merely to particularly describe representative
examples of the invention. Moreover, various features of the representative examples
and the dependent claims may be combined in ways that are not specifically enumerated
in order to provide additional useful examples of the present teachings.
[0022] In the following, a motor drive switch of the present invention will be described
with reference to FIG 1 to FIG 7.
[0023] First, a summary of a motor drive switch 20 will be described with reference to FIG
1A to FIG 1C.
[0024] The motor drive switch 20 is a double-pole double-throw switch used in a control
circuit 10 of a series-wound motor (hereinafter referred to as the motor) in which
a stator winding and an armature winding are connected in series.
[0025] The motor drive switch 20 is mounted on an electric tool main body (not shown). By
performing pull operation of a trigger 30 (refer to FIG 5), the motor of the electric
tool main body is started, and by performing returning operation on the trigger 30,
a brake is applied to the motor. The motor drive switch 20 is provided with a first
contact 21 and a second contact 22 interlocked with the movement of the trigger 30.
Further, a fixed end of the first contact 21 is connected to one end side terminal
(2) of a stator winding 11 of the motor, and a movable end of the first contact 21
can be switched between a power source P-side terminal (3) connected to the P side
of a power source E and an armature P-side terminal (1) connected to the P side of
an armature 14. A fixed end of the second contact 22 is connected to the other end
side terminal (5) of the stator winding 11 of the motor, and a movable end of the
second contact 22 can be switched between an armature P-side terminal (6) and an armature
N-side terminal connected to the N side of the armature 14.
[0026] As shown in FIG 1A, etc., the armature P-side terminal (1) to which the first contact
21 is connected and the armature P-side terminal (6) to which the second contact 22
is connected are connected to a brush P of the armature 14 via a conductive wire.
The armature N-side terminal (4) is connected to a brush N of the armature 14 via
a resistor 16 that can restrict a brake current. Further, the N terminal of the power
source E is connected to the brush N of the armature 14 via a fuse 15.
[0027] Due to the above construction, as shown in FIG 1A, when pull operation is performed
on the trigger 30 with the motor being stopped, the movable end of the first contact
21 (hereinafter referred to as the first contact 21) is first switched to the power
source P-side terminal (3) as shown in FIG 1B. Next, as shown in FIG 1C and FIG 2A,
the movable end of the second contact 22 (hereinafter referred to as the second contact
22) is switched to the armature P-side terminal (6). As a result, the stator winding
11 and the armature 14 of the motor are connected in series between the P terminal
and the N terminal of the power source E, whereby the motor is started.
[0028] As shown in FIG 2B, by performing returning operation on the trigger 30, the second
contact is first switched to the armature N-side terminal (4). Next, as shown in FIG
2C and FIG 1A, the first contact 21 is switched to the armature P-side terminal (1).
As a result, the stator winding 11, the armature 14, and the resistor 16 form a closed
loop, and a brake current flows through the stator winding 11 to brake the motor.
This causes the motor to stop.
[0029] As described above, when pull operation is performed on the trigger 30, the first
contact 21 is first switched, and then the second contact 22 is switched as shown
in FIG 1, so that an electric current flows through the stator winding 11 at the time
when the second contact 22 is connected to the armature P-side terminal (6). No electric
current flows through the stator winding 11 at the time when the first contact is
connected to the power source P-side terminal (3). Thus, if any contact sticking is
to be occurred with the passage of time, it occurs between the second contact 22 and
the armature P-side terminal (6). As shown in FIG 3A, when contact sticking occurs
between the second contact 22 and the armature P-side terminal (6) during the pull
operation of the trigger 30, the electric current for driving the motor flows through
the stator winding 11, and no abnormal electric current flows therethrough.
[0030] Further, when returning operation is performed on the trigger 30 in this state, the
first contact 21 is switched to the armature P-side terminal (1) as shown in FIG 3B.
In the state shown in FIG 3B, no voltage is applied to the stator winding 11, so that
no abnormal electric current flows through the stator winding 11. Further, even if
returning operation is performed on the trigger 30, the brake is not applied to the
motor, and thus it is possible to detect the occurrence of abnormality.
[0031] When returning operation is performed on the trigger 30 with the motor drive switch
20 being in the normal state, the second contact 22 is first switched, and then the
first contact 21 is switched as shown in FIG. 2A to FIG. 2C, so that an electric current
flows through the stator winding 11 at the time when the first contact 21 is connected
to the armature P-side terminal (1). No electric current flows through the stator
winding 11 at the time when the second contact 22 is connected to the armature N-side
terminal (4). Thus, if any contact sticking is to be occurred with the passage of
time by the returning operation of the trigger 30, it occurs between the first contact
21 and the armature P-side terminal (1). As shown in FIG 4A, in the case where contact
sticking occurs between the first contact 21 and the armature P-side terminal (1)
during the returning operation of the trigger 30, a brake current flows through the
stator winding 11 until the motor stops, and no abnormal electric current flows through
the stator winding 11.
[0032] Next, when pull operation is performed on the trigger 30, the second contact 22 is
switched to the armature P-side terminal (6) as shown in FIG 4B. In the state shown
in FIG 4B, no voltage is applied to the stator winding 11, so that no abnormal electric
current flows through the stator winding 11. Further, even if pull operation is performed
on the trigger 30, the motor does not rotate, and thus it is possible to detect the
occurrence of abnormality.
[0033] As shown in FIG 5A to FIG 5D, the motor drive switch 20 includes the trigger 30,
a switch case 35, the first contact 21, and the second contact 22. In the switch case
35, there is accommodated an operating portion 32 of the trigger 30 so as to be slidable
in the longitudinal direction (the horizontal direction in FIG 5A). Further, there
is accommodated in the switch case 35 a coil spring (not shown) that is biased to
push the operating portion 32 of the trigger 30 in a forward direction (in a direction
where the operating portion 32 protrudes from the switch case 35).
[0034] Further, as shown in FIG 5C, on the left-hand side of the lower portion of the switch
case 35, there are arranged terminals (1), (2), and (3), to which the first contact
21 is to be connected, along the sliding direction of the trigger 30 (See FIG 5A),
and on the right-hand side of the lower portion of the switch case 35, there are arranged
terminals (4), (5), and (6), to which the second contact 22 is to be connected, along
the sliding direction of the trigger 30.
[0035] The terminal (1) of the first contact 21 corresponds to the armature P-side terminal
(1), the terminal (2) thereof corresponds to one end side terminal (2) of the stator
winding 11, and the terminal (3) thereof corresponds to the power source P-side terminal
(3). The terminal (4) of the second contact 22 corresponds to the armature N-side
terminal (4), the terminal (5) thereof corresponds to the other end side terminal
(5) of the stator winding 11, and the terminal (6) thereof corresponds to the armature
P-side terminal (6).
[0036] As shown in FIG 5A, etc., the first contact 21 includes a strip-like metal plate
curved into a substantially arcuate configuration so as to be convex on the lower
side, with its center forming a fixed end 21 and its front and rear ends forming movable
ends 21f and 21h. Further, the fixed end 21c at the center of the first contact 21
is supported from below by the terminal (2) in the form of a scale. Thus, when the
first contact 21 is tilted around the fixed end 21c at the center (the terminal (2))
so as to be lower on the front side, the front side movable end 21f is connected to
the terminal (1), and the rear side movable end 21h is kept away from the terminal
(3) as shown in FIG 5A. That is, the first contact 21 is switched to the armature
P-side terminal (1) in this case.
[0037] When the first contact 21 is tilted around the fixed end 21c at the center (the terminal
(2)) so as to be lower on the rear side, the rear side movable end 21h is connected
to the terminal (3), and the front side movable end 21f is kept away from the terminal
(1) as shown in FIG 5B. That is, the first contact 21 is switched to the power source
P-side terminal (3) in this case.
[0038] Similarly, the second contact 22 includes a strip-like metal plate curved into a
substantially arcuate configuration so as to be convex on the lower side, with its
fixed end 22c at the center being supported from below by the terminal (5) in the
form of a scale. Further, operation is performed in a manner similar to that in the
case of the first contact 21, enabling movable ends 22f and 22h provided at the front
and rear ends of the second contact 22 to be respectively connected to the terminal
(4) and the terminal (5).
[0039] In the operating portion 32 of the trigger 30 there are embedded a first protrusion
36 pressing the upper surface of the first contact 21 and a second protrusion 37 pressing
the upper surface of the second contact 22. The first protrusion 36 and the second
protrusion 37 are pin-like members with the same length, with their distal ends being
beveled into a hemispherical configuration. Further, the first protrusion 36 and the
second protrusion 37 are respectively accommodated in vertical holes formed in the
lower surface of the operating portion 32 of the trigger 30, with their distal end
portions protruding therefrom. As shown in FIG 5D, the first protrusion 36 and the
second protrusion 37 are arranged to be offset each other in a sliding direction by
a distance X.
[0040] As shown in FIG 5A, in the state in which the trigger 30 is at the front end position,
the first protrusion 36 presses the upper surface of the distal end of the first contact
21, and the second protrusion 37 presses the upper surface of the distal end of the
second contact 22, so that the first contact 21 is connected to the terminal (1),
and the second contact 22 is connected to the terminal (4). That is, the motor control
circuit 10 becomes in the state as shown in FIG 1A and FIG 2C. As stated above, the
first protrusion 36 and the second protrusion 37 are arranged to be offset each other
in the sliding direction by the distance X. Thus, when pull operation is performed
on the trigger 30, and the first protrusion 36 and the second protrusion 37 slide
in the rearward direction on the upper surfaces of the first contact 21 and the second
contact 22 respectively, the first protrusion 36 first connects the first contact
21 to the terminal (3), and then the second protrusion 37 connects the second contact
22 to the terminal (6). That is, transferring from the state shown in FIG 1B, the
motor control circuit 10 becomes in the state as shown in FIG 2A, whereby the motor
is started.
[0041] When returning operation is performed on the trigger 30 and the first protrusion
36 and the second protrusion 37 slide in the forward direction on the upper surfaces
of the first contact 21 and the second contact 22 respectively, the second protrusion
37 which is situated on the front side of the first protrusion 36 in the sliding direction
first connects the second contact 22 to the terminal (4), and then the first protrusion
36 connects the first contact 21 to the terminal (1). That is, transferring from the
state shown in FIG 2B, the motor control circuit 10 becomes in the state as shown
in FIG 2C and FIG 1A, whereby a brake electric current flows through the stator winding
11 to brake the motor.
[0042] In the motor drive switch 20 of this example, configuration is made with respect
to the motor start operation such that, the first contact 21 is switched to the power
source P-side terminal (3) earlier than the switching of the second contact 22 to
the armature P-side terminal (6), as shown in FIG 1B. Thus, an electric current flows
through the stator winding 11 and the armature 14 at the time when the second contact
22 is switched to the armature P-side terminal (6). Thus, if contact sticking is to
be occurred with the passage of time, it occurs between the second contact 22 and
the armature P-side terminal (6).
[0043] As shown in FIG 3A, contact sticking occurs at the armature P-side terminal (6) of
the second contact 22. If stop operation is performed on the motor drive switch 20,
the first contact 21 is switched to the armature P-side terminal (1) as shown in FIG
3B, so that no electric current flows through the stator winding 11 of the motor.
That is, no abnormal electric current flows through the stator winding 11 of the motor
due to contact sticking.
[0044] As shown in FIG 2B, in the motor stop operation, configuration is made such that
the switching of the second contact 22 to the armature N-side terminal (4) is effected
earlier than the switching of the first contact 21 to the armature P-side terminal
(11). Thus, an electric current flows through the stator winding 11 and the armature
14 of the motor at the time when the first contact 21 is switched to the armature
P-side terminal (1). Thus, if contact sticking is to be occurred with the passage
of time, it occurs between the first contact 21 and the armature P-side terminal (1).
[0045] As shown in FIG 4A, contact sticking occurs at the armature P-side terminal (1) of
the first contact 21. If start operation is performed on the motor drive switch 20,
the second contact 22 is switched to the armature P-side terminal (6) as shown in
FIG 4B, so that the motor does not start, and the electric current ceases to flow
through the stator winding 11 of the motor. That is, no abnormal electric current
flows through the stator winding 11 of the motor in this case.
[0046] Thus, the stator winding of the motor may not be damaged, which can reduce the burden
of servicing.
[0047] The above construction may not be limited by the above-described example and may
various changes may be made without departing from the scope of invention. For example,
the above example shows that the mounting positions of the first protrusion 36 and
the second protrusion 37 are arranged to be offset from each other in the sliding
direction of the trigger 30 (a longitudinal direction) by the distance X, so that
there is a time lag in operational timing between the first contact 21 and the second
contact 22. However, it is also possible to provide a time lag in operational timing
between the first contact 21 and the second contact 22 by mounting the first protrusion
36 and the second protrusion 37 at the same position in the sliding direction (See
FIG 6E) and longitudinally offsetting bending positions of the first contact 21 and
the second contact 22 from each other.
[0048] That is, it is also possible to adopt a construction in which when sliding the trigger
30 in the backward direction, the first contact 21 is turned ON at a position on the
front side of the second contact by the distance X as shown in FIG 6C (i.e., the first
contact 21 is switched to the power source P-side terminal (3) earlier than the switching
of the second contact 22 to the armature P-side terminal (6)), and in which when returning
the trigger 30 in the forward direction, the second contact 22 is turned ON at a position
on the rear side of the first contact 21 by the distance X as shown in FIG 6D (i.e.,
the second contact 22 to the armature N-side terminal (4) is switched earlier than
the switching of the first contact 21 to the armature P-side terminal (11)).
[0049] Further, as shown in FIG 7C to FIG 7E, it is also possible to provide a first switch
210 including the first contact 21 and the terminals (1), (2), and (3), and a second
switch 220 including the second contact 22 and the terminals (4), (5), and (6), and
the trigger 30 that can operate the first switch 210 and the second switch 220.
[0050] More specifically, the first switch 210 is provided with a case 21c including the
first contact 22 and the terminals (1), (2), and (3), with an operating pin 21p being
attached to the case 21c so as to be capable of being displaced in the vertical direction.
Further, the operating pin 21p can be slid down against a spring force, whereby the
first contact 21 tilts to the left, with a movable end of the first contact 21 being
connected to the terminal (3) as shown in the lower portion of FIG 7E. Further, as
shown in FIG 7C, the operating pin 21p is configured to protrude from the case 21c
to a predetermined position by the spring force. The first contact 21 tilts to the
right with the terminal (2) serving as a fulcrum, and the movable end of the first
contact 21 is connected to the terminal (1).
[0051] The second switch 220 is of the same structure as the first switch 210. As shown
in the upper portion of FIG 7E, the operating pin 22p can be slid down against the
spring force, whereby the movable end of the second contact 22 is connected to the
terminal (6). Further, the movable end of the second contact 22 is connected to the
terminal (4) in a state where the operating pin 22p protrudes from the case 21c to
the predetermined position by the spring force.
[0052] There are formed on the operating portion 32 of the trigger 30 a first pressing surface
32a and a second pressing surface 32b capable of pressing the operating pin 21p of
the first switch 210 and the operating pin 22p of the second switch 220 respectively,
in the course of sliding.
[0053] The first pressing surface 32a and the second pressing surface 32b are inclined to
the same degree, and the first pressing surface 32a is arranged to be offset with
respect to the second pressing surface 32b by the distance X in the sliding direction,
as shown in FIG 7(B). Thus, by the pull operation of the trigger 30, the first pressing
surface 32a first presses the operating pin 21p of the first switch 210, and the first
contact 21 is connected to the terminal (3). Then, the second pressing surface 32b
presses the operating pin 22p of the second switch 220, and the second contact 22
is connected to the terminal (6).
[0054] By the returning operation of the trigger 30, the second pressing surface 32b is
caused to keep away from the operating pin 22p of the second switch 220 firstly, and
the second contact 22 is connected to the terminal (4). Then, the first pressing surface
32a is caused to keep away from the operating pin 21p of the first switch 210, and
the first contact 21 is connected to the terminal (1).
[0055] As described above, the motor drive switch of the present invention can be used in
a motor control circuit. Especially, it can also be used in electric power tools such
as miter saws, grinders, and electric screwdrivers etc.
1. A motor drive switch (20) comprising,
a first contact (21) connected to one end (2) of a stator winding (11) of a motor,
the first contact (21) being capable of switching between a power source first-side
terminal (3) connected to a first side (P) of a power source (E) and an armature first-side
terminal (1) connected to a first side (P) of an armature (14), and
a second contact (22) connected to the other end (5) of the stator winding (11), the
second contact (22) being capable of switching between the armature first-side terminal
(6) and an armature second-side terminal (4) connected to an second side (N) of the
armature (14),
the motor drive switch (20) being used in a motor control circuit (10) configured
such that the first contact (21) is switched to the power source first-side terminal
(3) and the second contact (22) is switched to the armature first-side terminal (6)
by a start operation of the motor, with the result that the stator winding (11) and
the armature (14) are connected in series between the first side (P) and the second
side (N) of the power source (E) to thereby start the motor,
the motor drive switch (20) further configured such that the first contact (21) is
switched to the armature first-side terminal (1), and the second contact (22) is switched
to the armature second-side terminal (4) by a stop operation of the motor, with the
result that the stator winding (11) and the armature (14) form a closed loop to thereby
brake the motor,
the motor drive switch (20) being characterized
in that the switching of the first contact (21) to the power source first-side terminal (3)
is configured to be effected earlier than the switching of the second contact (22)
to the armature first-side terminal (6) in the start operation of the motor, and
in that the switching of the second contact (22) to the armature second-side terminal (4)
is configured to be effected earlier than the switching of the first contact (21)
to the armature first-side terminal (1) in the stop operation of the motor.
2. The motor drive switch (20) according to claim 1, characterized
in that the motor drive switch (20) further comprises a trigger (30) performing the start
operation of the motor by sliding of the trigger (30) from a stop position to a start
position and performing the stop operation of the motor by returning of the trigger
(30) from the start position to the stop position,
in that the trigger (30) has a first protrusion (36) and a second protrusion (37) respectively
pressing the first contact (21) and the second contact (22) during the sliding,
in that each of the first contact (21) and the second contact (22) is formed in a scale-like
arcuate configuration whose center is supported by a fulcrum, each of the first contact
(21) and the second contact (22) tilting around the fulcrum as each location where
they are pressed by the first protrusion (36) or the second protrusion (37) varies,
thereby effecting switching of the contacts (21, 22), and
in that the first protrusion (36) and the second protrusion (37) are configured to be arranged
to be offset in the sliding direction, whereby a difference in switching time is caused
between the first contact (36) and the second contact (37).
3. The motor drive switch (20) according to claim 1, characterized
in that the motor drive switch (20) further comprises a trigger (30) performing the start
operation of the motor by sliding of the trigger (30) from a stop position to a start
position and performing the stop operation of the motor by returning of the trigger
(30) from the start position to the stop position,
in that the trigger (30) has a first protrusion (36) and a second protrusion (37) respectively
pressing the first contact (21) and the second contact (22) during the sliding,
in that each of the first contact (21) and the second contact (22) is formed in a scale-like
arcuate configuration whose center is supported by a fulcrum, each of the first contact
(21) and the second contact (22) tilting around the fulcrum as each location where
they are pressed by the first protrusion (36) or the second protrusion (37) varies,
thereby effecting switching of the contacts (21, 22), and
in that each bending position of the first contact (21) and the second contact (22) is configured
to be offset from each other in the sliding direction, whereby a difference in switching
time is caused between the first contact (21) and the second contact (22).
4. The motor drive switch (20) according to claim 1, characterized
in that the motor drive switch (20) further comprises a trigger (30) performing the start
operation of the motor by sliding of the trigger (30) from a stop position to a start
position and performing the stop operation of the trigger (30) by returning of the
trigger (30) from the start position to the stop position,
in that each of the first contact (21) and the second contact (22) is accommodated in a case
(21c, 22c) respectively, and operating pins (21p, 22p) protruding from the cases (21c,
22c) are pressed or depressed to effect switching of the contacts (21, 22), and
in that the trigger (30) has a first pressing surface (32a) and a second pressing surface
(32b) configured to press a first operating pin (21p) for the first contact (21) and
a second operating pin (22p) for the second contact (22) respectively, the first pressing
surface (32a) and the second pressing surface (32b) being offset from each other in
the sliding direction.
5. An electric power tool comprising the motor drive switch (20) according to any one
of claims 1 to 4.
1. Motorantriebsschalter (20) mit
einem ersten Kontakt (21), der mit einem Ende (2) einer Statorwicklung (11) eines
Motors verbunden ist, wobei der erste Kontakt (21) zwischen einem erstseitigen Anschluss
(3) einer Leistungsquelle, der an eine erste Seite (P) einer Leistungsquelle (E) verbunden
ist, und einem erstseitigen Anschluss (1) eines Rotors, der mit einer ersten Seite
(P) eines Rotors (14) verbunden ist, schalten kann, und
einem zweiten Kontakt (22), der mit dem anderen Ende (5) der Statorwicklung (11) verbunden
ist, wobei der zweite Kontakt (22) zwischen dem erstseitigen Anschluss (6) des Rotor
und einem zweitseitigen Anschluss (4) des Rotors, der mit einer zweiten Seite (N)
des Rotors (14) verbunden ist, schalten kann,
bei dem der Motorantriebsschalter (20) in einer Motorsteuerungsschaltung (10) verwendet
wird, die so konfiguriert ist, dass der erste Kontakt (21) zu dem erstseitigen Anschluss
(3) der Leistungsquelle geschaltet wird und der zweite Kontakt (22) zu dem erstseitigen
Anschluss (6) des Rotors geschaltet wird durch einen Startvorgang des Motors, mit
dem Ergebnis, dass die Statorwicklung (11) und der Rotor (14) in Serie zwischen der
ersten Seite (P) und der zweiten Seite (N) der Leistungsquelle (E) verbunden sind
um dadurch den Motor zu starten,
bei dem der Motorantriebsschalter (20) weiter so konfiguriert ist, dass der erste
Kontakt (21) zu dem erstseitigen Anschluss (1) des Rotors geschaltet wird, und der
zweite Kontakt (22) zu dem zweitseitigen Anschluss (4) des Rotors geschaltet wird,
durch einen Stoppvorgang des Motors, mit dem Ergebnis, dass die Statorwicklung (11)
und der Rotor (14) einen geschlossenen Kreis bilden, um dadurch den Motor zu bremsen,
der Motorantriebsschalter (20) dadurch gekennzeichnet ist,
dass in dem Startvorgang des Motors das Schalten des ersten Kontaktes (21) zu dem erstseitigen
Anschluss (3) der Leistungsquelle so konfiguriert ist, dass es früher ausgeführt wird
als das Schalten des zweiten Kontaktes (22) zu dem erstseitigen Anschluss (6) des
Rotors, und
dass in dem Stoppvorgang des Motors das Schalten des zweiten Kontaktes (22) zu dem zweitseitigen
Anschluss (4) des Rotors so konfiguriert ist, dass es früher ausgeführt wird als das
Schalten des ersten Kontaktes zu dem erstseitigen Anschluss (1) des Rotors.
2. Motorantriebsschalter (20) nach Anspruch 1, dadurch gekennzeichnet,
dass der Motorantriebsschalter (20) weiter einen Drücker (30) aufweist, der den Startvorgang
des Motors durch Gleiten des Drückers (30) von einer Stoppposition zu einer Startposition
ausführt, und den Stoppvorgang des Motors durch Zurückbringen des Drückers (30) von
der Startposition in die Stoppposition ausführt,
dass der Drücker (30) einen ersten Vorsprung (36) und einen zweiten Vorsprung (37) aufweist,
die den ersten Kontakt bzw. den zweiten Kontakt während des Gleitens drücken,
dass jeder von dem ersten Kontakt (21) und dem zweiten Kontakt (22) in einer waageförmigen
gebogenen Konfiguration ausgebildet sind, dessen Zentrum durch einen Drehpunkt gelagert
ist, jeder von dem ersten Kontakt (21) und dem zweiten Kontakt (22) sich um den Drehpunkt
neigt, während jede Stelle, wo sie durch den ersten Vorsprung (36) oder den zweiten
Vorsprung (37) gedrückt werden, variiert, und dadurch das Schalten der Kontakte (21,
22) ausgeführt wird, und
dass der erste Vorsprung (36) und der zweite Vorsprung (37) dazu konfiguriert sind, dass
sie in der Gleitrichtung versetzt angeordnet sind, wodurch ein Unterschied in der
Schaltzeit zwischen dem ersten Kontakt (36) und dem zweiten Kontakt (37) bewirkt wird.
3. Motorantriebsschalter (20) nach Anspruch 1, dadurch gekennzeichnet
dass der Motorantriebsschalter (20) weiter einen Drücker (30) aufweist, der den Startvorgang
des Motors durch Gleiten des Drückers (30) von einer Stoppposition zu einer Startposition
ausführt, und den Stoppvorgang des Motors durch Zurückbringen des Drückers (30) von
der Startposition in die Stoppposition ausführt,
dass der Drücker (30) einen ersten Vorsprung (36) und einen zweiten Vorsprung (37) aufweist,
die den ersten Kontakt bzw. den zweiten Kontakt während des Gleitens drücken,
dass jeder von dem ersten Kontakt (21) und dem zweiten Kontakt (22) in einer waageförmigen
gebogenen Konfiguration ausgebildet sind, dessen Zentrum durch einen Drehpunkt gelagert
ist, jeder von dem ersten Kontakt (21) und dem zweiten Kontakt (22) sich um den Drehpunkt
neigt, während jede Stelle, wo sie durch den ersten Vorsprung (36) oder den zweiten
Vorsprung (37) gedrückt werden, variiert, und dadurch das Schalten der Kontakte (21,
22) ausgeführt wird, und
dass jede gebogene Position des ersten Kontakts (21) und des zweiten Kontakts (22) dazu
konfiguriert ist, dass sie in der Gleitrichtung voneinander versetzt sind, wodurch
ein Unterschied in der Schaltzeit zwischen dem ersten Kontakt (21) und dem zweiten
Kontakt (22) bewirkt wird.
4. Motorantriebsschalter (20) nach Anspruch 1, dadurch gekennzeichnet
dass der Motorantriebsschalter (20) weiter einen Drücker (30) aufweist, der den Startvorgang
des Motors durch Gleiten des Drückers (30) von einer Stoppposition zu einer Startposition
ausführt, und den Stoppvorgang des Motors durch Zurückbringen des Drückers (30) von
der Startposition in die Stoppposition ausführt,
dass jeder von dem ersten Kontakt (21) und dem zweiten Kontakt (22) jeweils in einem Gehäuse
(21c, 22c) aufgenommen ist, und Betätigungspins (21p, 22p), die von den Gehäusen (21c,
22c) vorstehen, zum Ausführen des Schaltens der Kontakte (21, 22) gedrückt oder freigegeben
werden, und
dass der Drücker (30) eine erste Drückoberfläche (32a) und eine zweite Drückoberfläche
(32b) aufweist, die zum Drücken eines ersten Betätigungspins (21p) für den ersten
Kontakt (21) und eines zweiten Betätigungspins (22p) für den zweiten Kontakt (22)
jeweils konfiguriert sind, wobei die erste Drückoberfläche (32a) und die zweite Drückoberfläche
(32b) in der Gleitrichtung voneinander versetzt sind.
5. Elektrisches Kraftwerkzeug, das den Motorantriebsschalter (20) nach einem der Ansprüche
1 bis 4 aufweist.
1. Commutateur (20) de commande de moteur, comprenant
un premier contact (21) connecté à une extrémité (2) d'un bobinage (11) de stator
d'un moteur, le premier contact (21) étant apte à commuter entre une borne (3) de
premier côté de source d'énergie connectée au premier côté (P) d'une source (E) d'énergie
et une borne (1) de premier côté d'induit connectée au premier côté (P) d'un induit
(14), et
un deuxième contact (22) connecté à l'autre extrémité (5) du bobinage (11) de stator,
le deuxième contact (22) étant apte à commuter entre la borne (6) de premier côté
d'induit et une borne (4) de deuxième côté d'induit connectée à un deuxième côté (N)
de l'induit (14),
le commutateur (20) de commande de moteur étant utilisé dans un circuit (10) de commande
de moteur configuré de sorte à ce que le premier contact (21) est commuté sur la borne
(3) de premier côté de source d'énergie et le deuxième contact (22) est commuté sur
la borne (6) de premier côté d'induit par une opération de démarrage du moteur, de
telle sorte que la bobine (11) de stator et l'induit (14) sont connectés en série
entre le premier côté (P) et le deuxième côté (N) de la source d'énergie (E) et ainsi
démarrer le moteur,
le commutateur (20) de commande de moteur configuré en outre de façon à ce que le
premier contact (21) est commuté à la borne (1) de premier côté d'induit, et le deuxième
contact (22) est commuté à la borne (4) de deuxième côté d'induit par une opération
d'arrêt du moteur, de telle sorte que la bobine (11) de stator et l'induit (14) forment
une boucle fermée pour ainsi freiner le moteur,
le commutateur (20) de commande de moteur étant caractérisé
en ce que la commutation du premier contact (21) sur la borne (3) de premier côté de source
d'énergie est configurée pour être effectué plus tôt que la commutation du deuxième
contact (22) sur la borne (6) de premier côté d'induit dans l'opération de démarrage
du moteur, et
en ce que la commutation du deuxième contact (22) sur la borne (4) de deuxième côté d'induit
est configurée pour être effectué plus tôt que la commutation du premier contact (21)
sur la borne (1) de premier côté d'induit dans l'opération d'arrêt du moteur.
2. Le commutateur (20) de commande de moteur selon la revendication 1, caractérisé
en ce que le commutateur (20) de commande de moteur comprend en outre un déclencheur (30) effectuant
l'opération de démarrage du moteur par coulissement du déclencheur (30) d'une position
d'arrêt à une position de démarrage et effectuant l'opération d'arrêt du moteur par
retour du déclencheur (30) de la position de démarrage à la position d'arrêt,
en ce que le déclencheur (30) a une première protubérance (36) et une deuxième protubérance
(37) pressant respectivement le premier contact (21) et le deuxième contact (22) pendant
le coulissement,
en ce que le premier contact (21) et le deuxième contact (22) sont chacun formés dans une configuration
arquée de la forme d'une balance, dont le centre est supporté par un pivot, le premier
contact (21) et le deuxième contact (22) basculant chacun autour du pivot lorsque
chaque emplacement où ils sont pressés par la première protubérance (36) ou la deuxième
protubérance (37) varie, effectuant ainsi la commutation des contacts (21, 22), et
en ce que la première protubérance (36) et la deuxième protubérance (37) sont configurés pour
être en décalage l'un de l'autre dans la direction de coulissement, par lequel une
différence de temps de commutation est provoquée entre le premier contact (36) et
le deuxième contact (37).
3. Le commutateur (20) de commande de moteur selon la revendication 1, caractérisé
en ce que le commutateur (20) de commande de moteur comprend en outre un déclencheur (30) effectuant
l'opération de démarrage du moteur par coulissement du déclencheur (30) d'une position
d'arrêt à une position de démarrage et effectuant l'opération d'arrêt du moteur par
retour du déclencheur (30) de la position de démarrage à la position d'arrêt,
en ce que le déclencheur (30) a une première protubérance (36) et une deuxième protubérance
(37) pressant respectivement le premier contact (21) et le deuxième contact (22) pendant
le coulissement,
en ce que le premier contact (21) et le deuxième contact (22) sont chacun formés dans une configuration
arquée de la forme d'une balance, dont le centre est supporté par un pivot, le premier
contact (21) et le deuxième contact (22) basculant chacun autour du pivot lorsque
chaque emplacement où ils sont pressés par la première protubérance (36) ou la deuxième
protubérance (37) varie, effectuant ainsi la commutation des contacts (21, 22), et
en ce que chaque position pliée du premier contact (21) et du deuxième contact (22) est configuré
pour être en décalage l'un de l'autre dans la direction de coulissement, par lequel
une différence de temps de commutation est provoquée entre le premier contact (21)
et le deuxième contact (22).
4. Le commutateur (20) de commande de moteur selon la revendication 1, caractérisé
en ce que le commutateur (20) de commande de moteur comprend en outre un déclencheur (30) effectuant
l'opération de démarrage du moteur par coulissement du déclencheur (30) d'une position
d'arrêt à une position de démarrage et effectuant l'opération d'arrêt du moteur par
retour du déclencheur (30) de la position de démarrage à la position d'arrêt,
en ce que le premier contact (21) et le deuxième contact (22) sont chacun respectivement logés
dans un boîtier (21c, 22c), et des tiges opérantes protubérantes des boîtiers (21c,
22c) sont pressés ou relâchés pour effectuer la commutation des contacts (21, 22),
et
en ce que le déclencheur (30) a une première surface (32a) de pression et une deuxième surface
(32b) de pression configurées pour presser respectivement une première tige (21p)
opérante pour le premier contact (21) et une deuxième tige (22p) opérante pour le
deuxième contact (22), la première surface (32a) de pression et la deuxième surface
(32b) de pression étant en décalage l'une de l'autre dans la direction de coulissement.
5. Un outil électrique comprenant le commutateur (20) de commande de moteur selon l'une
des revendications 1 à 4.