United States Patent Arndt et a1.
[54] KEYBOARD APPARATUS WITH MOISTURE PROOF MEMBRANE [72] Inventors: Allen L. Arndt, Burnsville; Albert Z.
Kaszynski, St. Paul, both of Minn.
[15] 3,657,492 [4 1 Apr. 18, 1972 2,376,403 5/1945 Thompson et a1 ..200/5 E 2,875,287 2/1959 Van Sickle ..200/153 T X 3,240,884 3/ 1966 Boadle et a1. ..200/5 R 3,350,518 10/1967 Krakinowski et a1.
3,472,974 10/1969 McGough ..200/5 R 3,448,417 6/1969 Schiller et al ..200/5 E Primary Examiner-J. R. Scott At10rneyThomas J. Nikolai, Kenneth T. Grace, Donald W. Phillion and John P. Dority [5 7] ABSTRACT An electromechanical keyboard for use with a typewriter or other computer type data entry device designed to meet stringent environmental specifications. The electrical switches employed on the keyboard are totally enclosed in a metal compartment and are actuated through a deformable membrane such that moisture and dust cannot deleteriously affect the switches. Because the switches are contained within a metal compartment, a high degree of RFI shielding is afi'orded so that radiated emanations are low.
8 Claims, 2 Drawing Figures [it IHIIIIH '3: ll, 58 \52 58 I. 6011 E Illl 62 so KEYBOARD APPARATUS WITH MOISTURE PROOF MEMBRANE BACKGROUND OF THE INVENTION This invention relates generally to electromechanical keyboards, and more specifically to a new and improved design of such a keyboard which insures high reliability and substantial freedom from unwanted radio frequency interference radiation.
The keyboards used in equipment designed for military applications must meet stringent specifications in terms of shock and vibration, radio frequency interference, salt spray, etc. Most present day prior art keyboards of which we are aware are not constructed to meet these military requirements. Oftentimes the keyboard is not properly enclosed such that dust and water vapor can enter the mechanism and cause failures. Further, known designs are not sufficiently rugged to withstand the shock and vibration requirements. Further, known keyboards are oftentimes noisy in terms of RFI radiatron.
The design of the present invention obviates most of the defects in these prior art arrangements. The keyboard of the present invention comprises a plurality of pushbutton keys, which when depressed, causes reciprocal movement of an actuator rod. Operatively associated with the pushbutton rods are a plurality of pin-plunger type electrical switches. The pushbutton actuators are designed so as to prevent dust and moisture from entering and affecting their working parts. Similarly, the actuators have critical dimensions such that the parts thereof act as waveguides at the noise frequencies involved. The actuators are mounted in a first compartment with the pushbutton keys extending through the top thereof so as to be accessible to the operator. The pin-plunger type switches are mounted in a second compartment with their respective pin-plungers aligned with apertures formed in the top of the second compartment. When the first compartment along with its associated pushbutton actuators is juxtaposed on the second compartment, the actuator rods are aligned with the apertures in the top of the second compartment so that when a particular key is depressed, the actuator rod will be moved in a direction to operate the pin-plunger of the electrical switch. In order to prevent moisture from entering the second compartment and affecting the electrical switches a continuous flexible membrane such as a rubber sheet is disposed between the first and second compartments. As the actuator is depressed, the actuator rod deforms the rubber sheet in the area of the aperture in the top of the second compartment and is forced against the pin-plunger of the electrical switch.
It is accordingly an object of the present invention to provide a new and improved electrical keyboard mechanism.
It is another object of the invention to provide an improved keyboard which meets stringent military specifications.
Still another object of the invention is to provide an improved electrical keyboard which is extremely rugged, sealed against moisture and dust and which effectively reduces the amount of RF I noise radiated therefrom.
These and other objects of the invention will become apparent to those skilled in the art upon reading the following specification in light of the accompanying drawings.
DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view illustrating a preferred form of pushbutton type actuator used with the keyboard; and
FIG. 2, is a cross-sectional view of the keyboard assembly.
DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now to FIG. 1, there is shown a pushbutton which may be molded from plastic and which is cup-shaped.
that when the actuator rod is forced into the bore 18 a firm friction fit is established.
Theactuator assembly 10 of FIG. 1 is adapted to be mounted in a mounting plate. Specifically, the assembly includes acylindrical plunger guide 22 which is tubular in shape and which has ashoulder 24 extending inwardly at the bottom end thereof. The plunger guide is also provided with an outwardly extending shoulder orflange 26 which is adapted to rest against the mounting plate. The assembly is fastened in place by means of anut 28 which cooperates with threads formed on the external surface of theplunger guide 22.
Surrounding theactuator rod 20 is ashaft guide 30 having a diameter slightly less than the internal diameter of theplunger guide 22 so that it can operate in telescope fashion within theplunger guide 22.
Areturn spring 32 surrounds theactuator rod 20 and is disposed between the inwardly extendingshoulder 24 and the bottom surface of theshaft guide 30 so as to normally urge the shaft guide and pushbutton upward to the position illustrated in the drawing. It is to be especially noted that when the pushbutton is in its relaxed condition with no downward force applied thereto, theskirt 16 on thepushbutton 10 extends down sufficiently far to at least partially surround theplunger guide 22. Thus, the skirt serves to prevent foreign particles such as dust, moisture, etc. from entering the plunger guide and fouling the operation of the actuator.
AnE ring 34 is secured to the upper end of theactuator rod 20 and serves to hold theshaft guide 30 and thereturn spring 32 in position in the event that thepushbutton 10 is removed. Removal of the pushbutton may be desirable to permit replacement with pushbuttons having different alphanumeric symbols. When thepushbutton 10 is depressed by the operator's finger, thepushbutton 10, theactuator rod 20, and theshaft guide 30, move downward a distance determined by the spacing between the bottom surface of theE ring 34 and the top surface of thetubular plunger guide 22.
Now that the details of the actuator mechanism have been described in detail, consideration will be given to the keyboard assembly itself. Referring to FIG. 2, there is shown a cross-sectional view taken through the keyboard assembly. As is illustrated, the keyboard assembly includes acover member 36, having a top and four sides (only two of which are shown in the cross-sectional view) extending downward therefrom. Formed in the top of thecover 36 is a pattern ofapertures 38 which permits the pushbutton keys 10 (FIG. 1) to extend therethrough.
The keyboard assembly further includes achannel 40 having a bottom 42 and two upward extendingsides 44 and 46. Thesides 44 and 46 are bent inwardly at the top edge thereof to provide alip 48 and 50 which acts as a support for anapertured plate 52. The pattern of apertures in theplate 52 corresponds to the position of the actuator assemblies employed on the keyboard.
Mounted beneath theapertured cover plate 52 is a printedcircuit board 54 having a plurality of pin-plunger typeelectrical switches 56 mounted thereon. A typical example of a pin plunger type switch suitable for use in the present invention is disclosed in the McGall U.S. Pat. No. 1,960,020. This type of switch is commonly referred to in the art as a microswitch.Switches 56 include a pin-plunger 58 which, when depressed, causes contacts internal to the switch to close and establish continuity between predetermined conductors on the printedcircuit board 54.
As is illustrated in FIG. 2, the printedcircuit board 54 is supported from thecover plate 52 by means of aspacer 60 and asuitable fastener 62. The top surface of thecover plate 52 is covered by adeformable membrane 64 which serves as a gasket as will be further described hereinbelow.
Anactuator mounting plate 66 is located beneath thecover member 36 in a spaced apart relationship with respect to thecover plate 52 and the membrane orgasket 64 such that when the actuator assemblies are in their relaxed condition the lowermost ends of theactuator rods 20 are just touching the top surface of themembrane 64. Also, the spacing is such that the pushbutton extends through theapertures 38 in thecover member 36 so as to be accessible to the operator. Thus it can be seen that thecover member 36 and theactuating mounting board 66 form a first compartment having a perforated top 36, a bottom 66 along with side walls. The actuator assemblies of FIG. 1 are mounted on the mountingboard 66 which constitutes the bottom of the first compartment such that thepushbuttons 10 extend through theapertures 38 in the top 36. Theaperture plate 52 and thechannel 40 form a second compartment having a bottom and side walls and a plurality of pin-plungerelectrical switches 56 are mounted within this second compartment such that the pin-plungers 58 of the switches are aligned with the apertures in thetop plate 52. The continuousflexible membrane 64 is disposed between the bottom of the first compartment and the top of the second compartment and the two compartments are juxtaposed with respect to each other so that the actuator rods of the pushbutton actuators are aligned with the apertures in thetop 52 of the second compartment.
In operation, then, when the operator depresses one or more keys with his fingers, theactuator rods 20 move downward against the force of the return spring 32 (FIG. 1) and are constrained by theguides 22 and 30. The degree of travel of the actuator rods is sufficient to deform theflexible membrane 64 in the neighborhood of the apertures in thecover plate 52 to the extent that the membrane and actuator rods meet the pin-plunger on theswitches 56 to cause the switch to be operated.
Because thecover member 36 andchannel 40 are formed from metal, a high degree RFI interference shielding is obtained, to thereby prevent RF noise. Further, the ratio of the diameter to the length of theplunger guide 22 is calculated to give theplunger guide 22 the characteristics of a waveguide at the noise frequencies involved. As such theplunger guide 22 limits RFI radiation.
More specifically, in order to meet existing specifications covering electromagnetic interference, the total emission from the equipment must be below 80 db from 40 to 1,000 MH It can be shown that where the operating wave length is much much greater than the cut-off wave length )t the attenuation L caused by a wave guide of radius r and length d may be approximated by the formula L 54.5 i db Where k 3.4(r)
It is normally assumed that the emission from any one source should be less than 100 db in order to meet the existing specifications. Practical dimensions for aplunger guide 22 may be approximately r 0.50 cm.
d 4.0 cm.
From the foregoing formula it can be .seen that for the dimensions selected Ac 3.4 (r) and L 54.5% 128 Accordingly, for a high degree of radiation supression the length of theplunger guide 22 should be equal to or greater than four times its diameter.
Theflexible membrane 64 in the preferred embodiment is a silicone rubber sheet approximately 25 to durometer hardness. The gasket completely isolates the switches contained in the second compartment from the outside environment and prevents damage to the switches and other printed circuitry which might otherwise be caused by water and moisture.
The keyboard enclosure including thecover 36 and thebottom channel 40 can be formed using a welded construction to make the assembly extremely rugged and not subject to failure due to shock and vibration. Thus it can be seen that we have provided by our invention an electromechanical keyboard which is suited for use in military equipment.
The scope of the invention should not be restricted to the configuration illustrated in FIGS. 1 or 2. Many variations will become apparent to those skilled in the an after reading the specification. Accordingly, it is to be understood that the foregoing disclosure relates to only preferred embodiments of the invention and numerous modifications and alterations may be made therein without departing from the spirit and scope of the invention.
What is claimed is:
1. An electromechanical keyboard comprising:
a. a first compartment having a perforated top, a bottom and side walls I b. means for mounting a plurality of pushbutton operated plungers on said bottom such that said pushbuttons extend through the perforations in said top; each of said pushbutton operated plungers comprising;
a plunger rod;
a cup-shaped pushbutton having a bore formed in the bottom surface of said cup of a diameter slightly less than the diameter of said rod so as to create a press fit therebetween when said rod is inserted into said bore;
a cylindrical guide member secured to said rod, abutting the bottom surface of said cup-shaped pushbutton and extending beyond the rim of said cup-shaped pushbutton;
a tubular member having internally extending shoulder at one end thereof and an inside diameter slightly larger than the diameter of said cylindrical guide member to permit reciprocal movement of said guide member and rod within said tubular member when said pushbutton is depressed; and
a return spring surrounding said rod and disposed between said guide member and said shoulder;
c. a second compartment having a perforated top, a bottom and side walls;
d. means for mounting a plurality of pin-plunger type electrical switches within said second compartment such that said pin-plungers are aligned with the perforations in the top of said second compartment; and
e. a continuous flexible membrane disposed between the bottom of said first compartment and the top of said second compartment; and
f. means for securing said first compartment in a juxtaposed position with respect to said second compartment such that said plungers are in alignment with the perforations in the top of said second compartment.
2. A pushbutton operated plunger comprising:
a. a plunger rod b. a cup-shaped pushbutton having a bore formed in the bottom surface of said cup of a diameter slightly less than the diameter of said rod so as to create a press fit therebetween when said rod is inserted into said bore;
c. a cylindrical guide member secured to said rod abutting the bottom surface of said cup-shaped pushbutton and extending beyond the rim of said cup-shaped pushbutton;
d. a tubular member having internally extending shoulder at one end thereof and an inside diameter slightly larger than the diameter of said cylindrical guide member to permit reciprocal movement of said guide member and rod within said tubular member when said pushbutton is depressed; and
e. a return spring surrounding said rod and disposed between said guide member and said shoulder.
3. Apparatus as in claim 1 wherein said membrane is a silicone rubber sheet approximately 25 to 30 durometer hardness.
4. Apparatus as in claim 2 wherein the length of said tubular member is at least four times its diameter.
5. An electromechanical keyboard comprising:
a. a first metal compartment having a perforated top, a bot- 7 tom and side walls;
b. plunger guide means for mounting a plurality of pushbutton operated plungers on said first compartment bottom such that said pushbuttons extend through the perforations in said top;
each of said pushbuttons comprising;
a body and a hollowed-out portion surrounded by a skirt;
a tubular shaft guide within said hollowed-out portion and extending beyond the rim of said skirt;
0. a plurality of plunger rods, each plunger rod passing through an associated plunger guide and secured to an associated pushbutton for permitting reciprocal movement of said shaft guide in said plunger guide;
d. a second metal compartment having a perforated top, a
bottom and side walls;
e. means for mounting a plurality of electrical switches within said second compartment and in alignment with the perforations in the top of said second compartment;
. a continuous flexible membrane disposed between the bottom of said first compartment and the top of said second compartment; and,
g. means securing said first compartment in a juxtaposed position with respect to said second compartment for aligning said plunger guides with the perforations in the top of said second compartment.
6. The electromechanical keyboard of claim 5 wherein each of said plunger guides has the characteristics of a wave guide for providing to transmission therethrough from said second compartment to said first compartment of noise signals of frequencies from 40 MH to 1,000 MH an attenuation of at least 80 db.
7. A pushbutton operated plunger, comprising:
a. a plunger rod;
b. a pushbutton comprising;
a body and a hollowed-out portion surrounded by a skirt;
a tubular shaft guide within said hollowed-out portion and extending beyond the rim of said skirt;
means for securing said plunger rod to said body and through said shaft guide;
a tubular plunger guide having an internally extending shoulder at one end and an inside diameter of a length extending to the other end and an outside diameter at said other end for permitting reciprocal movement of said plunger guide within said skirt and over said shaft guide;
d. a spring surrounding said plunger rod and disposed within the inside diameter of said plunger guide and between said shaft guide and the internally extending shoulder of said plunger guide when said plunger rod is secured to said body for permitting reciprocal movement of said shaft guide and said plunger rod within said inside diameter and said internally extending shoulder, respectively, of said plunger guide.
8. The pushbutton operated plunger of claim 7 wherein said length is at least four times said inside diameter giving said plunger guide the characteristics of a wave guide for providing to transmission therethrough of noise signals of frequencies from 40 MH to 1,000 MH, and attenuation of at least db.