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Description  |
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BACKGROUND OF THE INVENTION
The invention relates to keyboard switches and is directed more
particularly to a low-profile keyboard switch having an improved guide
structure.
Prior to the present invention pushbutton keyboard switches have included
keys having central plungers which were guided along relatively long
tubular channels or guides formed in the cover surface of the keyboard
switch housing, as is disclosed, for example, in German Patent No. 33 02
793. The lengths of these plungers and guides have been thought to be
necessary in order to prevent the actuating force of the key from
increasing noticeably when the key is pressed at a point away from its
center. Such an increase in force results from the tilting of the plunger
in its guide.
According to prevailing ergonomic standards for alphanumeric keyboards,
e.g., video work stations, the average overall height of the keyboard must
not exceed 30 mm. Because of the just described tilting problem, it has
not been possible to meet these standards with keyboard switches of the
above mentioned type.
SUMMARY OF THE INVENTION
In accordance with the present invention there is provided an improved
keyboard switch of the aforementioned type which has a low profile and
which may be operated with minimal force.
Generally speaking, the present invention contemplates a keyboard in which
each key assembly includes a key having a downwardly projecting central
plunger and a downwardly projecting leg or skirt, and a guide member
having a substantially horizontal central opening adapted to receive the
plunger and a substantially vertical outer surface adapted to serve as a
bearing surface. In the preferred embodiment the inner dimension of the
skirt is larger than the outer dimension of the guide member and the
spaces between the skirt and the guide member are occupied by horizontally
projecting slide cams. In use, the interior of the central opening and the
exterior surface of the guide member serve as horizontally spaced vertical
guide surfaces which guide the vertical motion of the key.
The advantages of the present invention result from the fact that the key
is provided with a improved guide structure which allows the length of the
plunger guide to be greatly reduced and which causes any off-center
actuation of the key to produce only a slight increase in the key
actuating force.
DESCRIPTION OF THE DRAWINGS
The invention will be described with reference to the accompanying
drawings, in which:
FIG. 1 is an enlarged cross sectional view of a first type of prior art
keyboard switch;
FIG. 2 is an enlarged cross sectional view of a first embodiment of a
keyboard switch constructed in accordance with the invention;
FIGS. 3 and 4 are enlarged cross sectional views of a second embodiment of
a keyboard switch constructed in accordance with the invention;
FIG. 5 is an enlarged cross sectional view of a second type of prior art
keyboard switch;
FIG. 6 is an enlarged cross sectional view of a third embodiment of a
keyboard switch constructed in accordance with the invention; and
FIG. 7 is an exploded partial perspective view of a part of the keyboard
frame of FIG. 3 together with the associated keyboard switch elements.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to FIG. 1, there is shown a cross sectional view of a
conventional type of keyboard switch assembly. This assembly includes a
keyboard switch housing or guide 10 having an open bottom which is closed
by a bottom plate 11 that supports contacts 11a. Resting on bottom plate
11 is a rubber-elastic switching dome 12 which has a contact bead 12a in
its center. Resting on the top of dome 12 is a key plunger 15 which is
vertically displaceable in a tubular guide channel 13 formed within
housing 10. The length of this channel is increased by providing a
projecting part 10a which extends upwardly from the upper surface of
housing 10. The plunger 15 is headed by a keypad 16 which has an actuating
surface 16a.
Upon actuating the key in the center of the surface 16a, with the exception
of small frictional forces, only the counterforce of the switching dome 12
has to be overcome. As can be seen from the force-distance diagram, the
counterforce at first increases as the key moves, reaching a maximum value
F.sub.N after travelling distance S.sub.X and then decreases again, owing
to the collapse of switching dome 12, as it travels the remaining distance
S.sub.H. This switch travel is ended as soon as the contact bead 12a comes
into contact with contacts 11a.
During actual use, keys are almost always pressed at points that are off
center, particularly when they form part of a keyboard array. In such
cases the actuation force F.sub.B may act upon the rim portion of the
surface 16a, as is shown in FIG. 1. If, as shown in FIG. 1, actuation
force F.sub.B acts at the outer rim portion of the surface 16a of keypad
16 then the key element including plunger 15 and keypad 16 is subjected to
a tilting moment, causing one side of plunger 15 to be pressed against the
upper portion of channel 13 and the other side of plunger 15 to be pressed
against the lower side of channel 13. At the time when dome 12 is in the
position which offers the greatest counterforce F.sub.N, the resisting
forces F.sub.S1 and F.sub.S2 which are associated with these contacts
manifest themselves as shown in the force diagram and act at angles which
are substantially determined by the types of materials used. In order to
enable a better comparison, all examples to be described hereinafter are
based on the same assumed conditions. The intersection of resisting force
vector F.sub.S1 and the actuation force vector F.sub.B, and the
intersection of resisting force vector F.sub.S2 and dome force vector
F.sub.N are connected by the so-called Culmann's straight line C. The
angular position of such a straight line is a direct measure of the
increase of the actuation force F.sub.B, with force F.sub.B increasing as
straight line C becomes more nearly horizontal.
From the triangle of forces shown in FIG. 1, the increase of actuation
force F.sub.B, as compared to the dome force F.sub.N, is calculated at
0.15N, which means an increase in force of almost 40% in this case.
FIG. 2 is a cross sectional view of a first embodiment of the keyboard
switch of the invention in which both keypad 26 and plunger 25 are guided.
FIG. 2 shows a keyboard switch assembly having a keyboard switch housing
or guide member 20 which may be circular and which has an open bottom. The
underside of housing 20 is closed by a bottom plate 21 having contacts
21a. Bottom plate 21 supports a rubber-elastic switching dome 22 which is
provided with a contact bead 22a at its center. Resting on the top of dome
22 is a plunger 25 which is capable of sliding vertical motion within a
central opening 23 defined by member 20. Significantly, the vertical
dimension of opening 23 is substantially equal to the thickness of
material that forms member 20. Extending downwardly from upper end of key
26 is a generally bell-shaped peripheral member or skirt 26b which fits
over cylindrical guide member 20. The inner surface of skirt 26a is spaced
a small distance apart from the outer surface of member 20 and is
generally parallel thereto. This skirt extends down so far that its lower
rim portion, in the actuated state of the keyboard switch, will not touch
bottom plate 21. Positioned along the inside edge of this lower rim are at
least four crosswisely disposed slide cams or members 28 which, with the
exception of a small clearance space, occupy the space between guide
member 20 and skirt 26b. Instead of a discrete number of slide cams 28, a
continuous slide ring (not shown) may be used.
If, as shown in the force diagram of FIG. 2, an actuation force F.sub.B
acts at the outer rim portion of actuating surface 26a of key 26, then the
plunger 25 will press against the right hand side of central guide hole
23. At the same time, one or more slide cams 28 will press against the
smooth outer surface of guide member 20.
After travelling through distance S.sub.X, the counterforce of the dome 22
will have reached its maximum value F.sub.N, as can be seen from the
force-distance diagram. At this time, the resisting force vectors F.sub.S1
and F.sub.S2 shown in FIG. 2 appear at the indicated points. Through the
intersection points with the force vectors F.sub.B or F.sub.N
respectively, there is also drawn a Cullmann's straight line C. Compared
with the straight line C shown in FIG. 1, this line will be seen to be
substantially steeper. As is shown in the graphical calculation in the
force triangle next to this diagram, the actuation force F.sub.B. compared
to the dome force F.sub.N, has only increased by 0.1N and, consequently,
is only about half as great as with the keyboard switch shown in FIG. 1.
FIGS. 3 and 4 are cross sectional views of a second embodiment of the
keyboard switch of the invention in which both the plunger 35 and the
outer edge of key 36 are guided. FIGS. 3 and 4 show a keyboard switch
having a square guide member 30 (FIG. 4) and a square key 36 having an
actuating surface 36a. FIG. 3 is a sectional view taken on line III--III
of FIG. 4. Member 30 has an open bottom and is closed by a bottom plate 31
which has contacts 31a. A rubber-elastic switching dome 32 which, via the
bottom plate 31, is firmly connected to member 30, rests on the bottom
plate 31. Above the contacts 31a and at a spacing corresponding to the
switch travel S.sub.H, the switching dome 32 is provided with a contact
bead 32a at its center. The top of dome 32 is in contact with the plunger
35 which is vertically guided by a part 30a which projects upwardly from
the top of guide member 30. It should be noted that only the thin upper
portion of the part 30a is in contact with plunger 35.
From diagonally opposite corners of square keypad 36 there extends, in
generally parallel relationship to plunger 35, at least two flexurally
stiff peripheral members or legs 37 which are resistant to bending and
have L-shaped cross sections (see FIG. 4). These legs are preferably flush
with the outer corners of keypad 36. In the top of guide member 30, there
are provided passages 34 which have cross sectional shapes that are
similar to those of legs 37 and which allow legs 37 to project into the
interior hollow space of the keyboard switch assembly. As will be seen
from FIG. 4, two guide ridges 39 are provided in the free corners of the
guide member in generally parallel relationship to the faces of legs 37.
Each of legs 37 has at least one horizontally projecting slide cam 38
which, except for a small clearance space, is in contact with the guide
ridges 39. As will be seen from FIG. 3, these guide ridges 39 are somewhat
recessed inwardly with respect to passages 34, so that a step-shaped
offset or shoulder results.
When the key is inserted, the slide cams 38 snap into place below this
offset. In this way the key is, in a simple manner, detachably locked
inside the keyboard switch assembly. In its normal position, plunger 35
rests lightly on the top of dome 32.
If, as shown in FIG. 3, an actuation force F.sub.B acts at the outer rim
portion of actuating surface 36a of key 36, then the plunger 35 Will press
against the right hand side of central guide hole 33. At the same time,
one or more of slide cams 38 will press against the inner surfaces of
respective guide ridges 39.
After travelling through distance S.sub.X, when the counterforce of the
dome 32 reaches its maximum value F.sub.N (see force-distance diagram),
the resisting forces F.sub.S1 and F.sub.S2 shown in FIG. 3, appear at the
indicated points. The Culmann's straight line C drawn through the
previously mentioned intersection points assumes the same angle as in the
example of FIG. 2, so that the same values are calculated, as can be seen
from the force triangle of FIG. 3.
In the case of keyboard switches employing keypads which are several times
as wide as those discussed earlier and which are shown in FIGS. 5 and 6
(and which each only have one plunger) substantially higher tilting
moments occur as a result of the greater overhang of the keypad.
FIG. 5 is a cross sectional view of another type of prior art keyboard
switch. The keyboard switch housing 50 has a width roughly corresponding
to that of the keypad and has an open bottom. Inside the housing 50 there
is located a switching dome 52 which rests on a bottom plate 51 closing
the housing 50 from below. As with all previously described embodiments,
contacts 51a and a contact bead 52a oppose each other at the spacing of
the switch travel S.sub.H. Resting on the top of dome 52 is a plunger 55
which has a long guide channel 53 extending through the entire thickness
of housing 50, including a portion 50a which extends upwardly from the top
thereof. To the plunger 55 there is connected an extra wide keypad 56
which has an actuating surface 56a that extends across its entire width.
If, as shown in FIG. 5, an actuation force F.sub.B acts at the outer rim of
the surface 56a of keytop 56, a high tilting moment will occur which
creates a high magnitude resisting forces F.sub.S1 and F.sub.S2. When the
counterforce produced by switching dome 52 reaches its maximum value
F.sub.N after travelling distance S.sub.X, this tilting moment may be so
great as to lead to a breakage of plunger 55. This is because, according
to the force triangle and owing to the nearly horizontally extending
Culmann's straight line C, the actuation force F.sub.B necessary to
displace key 55/56 with respect to the dome force F.sub.N. increases by
1.5N, which corresponds to a 400% increase in force.
Compared to this, the keyboard switch shown as a third embodiment of the
invention in FIG. 6 has substantially more favorable force values.
Since the construction of the keyboard switch embodiment of FIG. 6
corresponds to that of the embodiments shown in FIGS. 3 and 4, the
structure of the keyboard switch of FIG. 6 will not be discussed in detail
herein. The only difference is that the legs 67 are not flush with the
outer corner of the keypad 66, but are recessed somewhat toward the inside
thereof. Accordingly, the top side of the housing 60 is provided with
passages for legs 67. The guide ridges 69 which can be seen in FIG. 6 are
chamber walls which separate the actual switch area from the guide area so
that any dirt or humidity penetrating through the passages 64 is kept away
from the switch contacts. In the embodiment shown in FIG. 3, it is
likewise possible to prevent dirt penetration by extending guide ridges 39
to form a closed square frame.
If, as shown in FIG. 6, an actuation force F.sub.B acts at the outer rim of
surface area 66a of keypad 66, then the plunger 65 is in contact with the
right hand side of central guide hole 63. At the same time, one or more of
the slide cams 68 will press against the associated guide ridges 69.
When the counterforce of the switching dome 62 reaches its maximum value
F.sub.N after travelling distance S.sub.X. as shown in the force-distance
diagram of FIG. 6, resisting forces F.sub.S1 and F.sub.S2 appear at the
indicated points. The Culmann's straight line C which is drawn through the
previously mentioned intersection points, assumes a substantially steeper
angle than the corresponding line C of FIG. 5. As is evident from the
graphical calculation in the associated force triangle, the increase in
actuation force F.sub.B is 0.9N, about 15% of the value associated with
the embodiment of FIG. 5. This comparison clearly shows the effect of the
keypad guide member in addition to the effect of the plunger guide member.
As mentioned previously, flat keyboard switches are required primarily in
connection with alpha-numeric keyboards. Whereas earlier keyboards Were
mainly composed of individual key assemblies, it has recently become
common practice to use keyboard frames in which all key assemblies share a
common housing. The bottom surfaces of such keyboard frames are subdivided
into a great number of compartments each of which contains the contacts of
one switch.
Referring to FIG. 7, there is shown a part of an exploded perspective view
of such a keyboard frame 70. In FIG. 7 the guiding facilities are visible
from the outside because the key elements 75-77 are shown in the upper
part of the drawing. These key elements 75-77 correspond to those of the
embodiment described in connection with FIG. 3. Each key element consists
of a plunger 75 formed integrally with a keypad 76. The keytops are
provided with diagonally opposite legs 77 having L-shaped cross sections
which are flush with the outer corners of the keytop 76. On the inner
surfaces of the ends of these legs, slide cams 78 are disposed. The
keyboard frame 70 comprises parts 70a which project upwardly from the top
surface with guide holes 73 for receiving respective plungers 75. In order
to receive members 77 keyboard frame 70 is provided with passages 74
having cross sectional shapes corresponding to those of legs 77. Together
with the interior compartment walls, these passages serve as guides for
legs 77.
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