Electronic equipment

An electronic equipment comprises key input means having a plurality of key input areas, a frame member for sandwiching a metal plate therein, and printed circuit means having a key input circuit adapted to be closed by a depression force from the key input area and having an electronic part connected thereto. The key input means covers an upper surface of the frame member. The frame member has convey means for conveying the depression force from the key input area to the printed circuit means.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to electronic equipment, and more 
particularly to electronic equipment having a plurality of key input units 
such as an electronic desk-top calculator. 
2. Description of the Prior Art 
In prior art electronic equipment of this type, a key input unit comprises 
movable contacts formed by conductive rubber and key tops, and a printed 
circuit board arranged on the movable contacts. A separate display unit 
and a separate unit for accommodating a power supply such as batteries are 
held by separate members. 
Because of such construction, the number of parts is large and the number 
of assembling steps is also large and associated management requirements 
such as parts management are complex. As a result, the cost of the 
equipment increases. 
A thin desk-top calculator has been recently marketed but it is weak in 
strength because of thin structure. 
In a key input unit of the prior art desk-top calculator, stationary 
contacts for key input are formed on a printed circuit board in a 
predetermined pattern. Movable contacts made of silicone conductive rubber 
are vertically movably held at positions facing the pattern, and separate 
key tops are arranged on the movable contacts. 
With such a structure, the conductive rubber of the movable contacts is 
separate from a frame and it must be mounted at a predetermined position 
in an assembling step. Further, a plurality of separate key tops must be 
fitted to key top holes formed in the frame. If the frame is upset or 
vibrated during the assembling step, the key tops are scattered here and 
there. Thus, the number of steps increases and the handling is very 
troublesome. 
When a thin desk-top calculator which is convenient to carry is desired, 
there is a limit to the thickness of the silicone rubber. It is difficult 
to provide a click feeling with a short key stroke and this may cause 
misoperation. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide electronic equipment 
having a key input function which is new in structure and effective. 
It is another object of the present invention to assure a sufficient 
strength of electronic equipment when it is constructed in a thin 
structure. 
It is other object of the present invention to enhance the strength and 
simplify the structure of electronic equipment by insert molding. 
It is other object of the present invention to facilitate insert molding of 
a metal plate. 
It is other object of the present invention to use a projection of a metal 
plate formed by insert molding in order to hold an electronic part. 
It is other object of the present invention to provide a projection formed 
by insert molding as a contact. 
It is other object of the present invention to form a key input unit very 
easily. 
It is other object of the present invention to use contact means to hold a 
part. 
It is other object of the present invention to simply form a key input unit 
by insert molding. 
It is other object of the present invention to allow a metal plate formed 
by insert molding in a frame to be positioned at a predetermined position 
so that a variation of position of the metal plate between one frame and 
another frame is eliminated. 
It is other object of the present invention to hold a thick part such as a 
display or a solar cell by a metal plate. 
It is other object of the present invention to form closing means by insert 
molding when a metal plate having a portion for forming the closing means 
is formed in a frame by insert molding. 
It is other object of the present invention to simultaneously form closing 
means and a projection for holding a part by insert molding. 
It is other object of the present invention to simultaneously form closing 
means and a contact to be contacted to printed circuit means by insert 
molding. 
It is other object of the present invention to exactly form a metal plate 
by insert molding. 
It is other object of the present invention to provide a very thin 
electronic equipment. 
The other objects of the present invention will be apparent from the 
following description of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
FIG. 1 shows a structure of a thin metal plate 1 which is an important 
element of the present invention. 
The thin metal plate 1 is formed from a resilient material such as 
phosphor-bronze, stainless steel or brass by etching or pressing and it 
has a thickness of approximately 50-100 .mu.m. 
A key input section of the thin metal plate 1 forms closing means of a key 
input circuit of a printed circuit board to be described later and it has 
a plurality of upwardly bulged semi-spherical domes 1a. At a center, that 
is, an apex of each of the domes 1a, a downward recess 1b is formed. The 
recess 1b serves as a contact of a movable key contact as will be 
explained later. Thus, each movable contact is formed by the dome 1a, a 
periphery 1aa surrounding the dome 1a and the recess 1b. 
The domes 1a are integrally formed in one sheet of the thin metal plate 1 
and they are divided into contact blocks B.sub.1 -B.sub.8 which are 
interconnected by narrow connecting areas 1c. Numeral 1d denotes an outer 
frame which is also connected to the contact blocks by the narrow 
connecting areas 1c. 
Numerals 1e and 1e' denote positioning holes to which positioning pins of a 
mold are fitted. 
On the other hand, an opening 1h for holding a display and an opening 1i 
for holding a power supply unit such as a solar cell are formed 
contiguously to the contact blocks of the thin metal plate 1. 
The contact blocks B.sub.1 -B.sub.8 are bases for supplying key input 
information to an LSI which performs arithmetic operations of the desk-top 
calculator. FIG. 2 shows a block diagram of a desk-top calculator as an 
example of the electronic equipment. 
Key input signals in a key input unit of FIG. 2 are produced by shorting 
any two of signal lines K.sub.1 -K.sub.8. 
For example, when the signal lines K.sub.4 and K.sub.6 are shorted, a 
signal is read by an arithmetic operation unit and "1" is displayed on a 
display unit. 
When a desk-top calculator key layout of a cover sheet 4 of a frame 2 shown 
in FIG. 5 is employed to supply key input signals ".", "0", "1", "2", "3", 
and "%.+-." to the arithmetic operation unit, those terminals correspond 
to the contact block B.sub.5 in FIG. 1. 
In FIG. 1, "9" is included in the block B.sub.4 of the K.sub.8 line 
because of the desk-top calculator key layout. 
The contact blocks B.sub.1 -B.sub.8 of FIG. 1 are configured to minimize 
the number of the contact blocks on a single side printed circuit board 3 
for a pattern of the key input circuit corresponding to the key input unit 
of FIG. 2. 
The thin metal plate 1 having such a structure is insert-molded into a 
frame body 2' made of insulating high molecular material to form the frame 
2. 
When the material of the frame body 2' is thermoplastic material such as 
ABS resin, styrol resin or polycarbonate resin, the thin metal plate 1 is 
insert-molded by injection molding, and when the material is a 
thermosetting resin such as epoxy resin or phenol resin, the thin metal 
plate 1 is insert-molded by compression molding. The insert-molded metal 
plate is shown in FIG. 3 in which like elements to those shown in FIG. 1 
are designated by like numerals and necessary portions of the domes 1a are 
exposed out of the frame body 2'. 
In FIGS. 1 and 3, numeral 1j denotes a grounding projection for maintaining 
a ground pattern 3c formed on the printed circuit board 3 shown in FIG. 5 
to the same potential as that of the outer frame 1d. 
Small holes 2f formed in the outer periphery of the frame 2 are formed by 
registering the mold having flat-end pins of a small diameter with the 
thin metal plate 1 in order to position the thin metal plate 1 at the 
center, thicknesswise, of the frame body 2'. Since the thin metal plate is 
molded while it is positioned and held in place, the deformation and the 
shift of the thin metal plate 1 are prevented even when the molding 
material is filled into the mold at a high pressure. 
During the insert molding, the thin metal plate 1 is also held by a flat 
area of the mold at positions other than those facing the small holes 2f. 
The thin metal plate 1 is thus held by the mold at all connecting area 1c, 
at peripheries of all domes 1a and openings 1h and 1i, and at the 
projection 1j. Because the thin metal plate 1 is uniformly held at a 
number of positions, it is inserted into the frame body 2' at its exact 
proper position. The areas to be exposed are exposed by the insert molding 
and hence it is not necessary to expose them by grinding portions of the 
frame body. Therefore, the work is very efficient. 
Since the exposed areas are held by the mold during the insert molding, 
they are precisely positioned relative to the frame body. As a result, a 
key stroke is kept constant and the parts are held precisely. 
In the present embodiment, as described above, the projections for holding 
the parts, the movable contacts and the connecting areas are 
simultaneously formed by insert molding. 
A sectional view of a structure of the frame comprising the frame body 2' 
and the thin metal plate 1 after insert molding is shown in FIG. 4. As 
seen from FIG. 4, the top of the dome 1a is substantially flush with the 
upper surface of the frame 2 and the recess 1b is exposed and the upper 
and lower surfaces of the connecting area 1c are also exposed. The 
connecting areas 1c are cut off after the insert molding as shown in FIG. 
6 so that the electrical connections between the contact blocks B.sub.1 
-B.sub.8 and the outer frame 1d are broken. 
However, as shown in FIG. 6, a connecting area 1g is simply cut off but a 
connecting area 1f is folded so that it is connected to a contact pattern 
3a of the printed circuit board 3. 
In this manner, the contact blocks B.sub.1 -B.sub.8 are connected to the 
key signal lines on the printed circuit board by at least one folded 
connecting area 1f. 
A rectangular opening 2y shown in FIG. 3 is an opening into which an LSI 8 
to be described later is fitted. When the desk-top calculator is assembled 
as shown in FIG. 5, the LSI 8 is fitted to the opening 2y and the 
thicknesses of the frame 2 and the LSI 8 are selected such that the upper 
surface of the LSI 8 is substantially flush with the upper surface of the 
frame 2. Thus, when the cover sheet 4 is applied to the upper surface of 
the frame 2, the portion facing the LSI 8 does not project or sink and 
good appearance is attained and the cover sheet 4 is difficult to tear 
off. With this construction, the thickness of the desk-top calculator can 
be reduced to the thickness of the LSI 8. 
A developed perspective view of the desk-top calculator assembled by using 
the frame 2 having the connecting areas 1c cut off is shown in FIG. 5. 
In FIG. 5, numeral 4 denotes the cover sheet which is made of transparent 
material having an appropriate flexibility such as vinyl chloride, 
polyester, polycarbonate or urethane, and printing is carried on a back 
surface thereof except in areas for a display window 4a and a window 4b 
for the solar cell. Key symbol marks are marked on the key area and a 
desk-top calculator model number or the like is also printed. It is 
fixedly bonded to the upper surface of the frame 2 in an assembling step. 
Numeral 3 denotes the printed circuit board including the key input 
circuit. It is a single side printed circuit board having a copper 
laminated plate etched into a predetermined pattern. A plurality of key 
inputting stationary contacts 3b are formed in one-to-one correspondence 
to the domes 1a of the frame 2. The ground pattern 3c serves to connect 
the outer frame 1d to ground potential. It always contacts to the 
projection 1j formed in the thin metal plate 1 to conduct static 
electricity discharged from the exterior of the desk-top calculator to the 
outer frame 1d to prevent the malfunction and the destruction of the LSI 8 
by the static electricity. 
The LSI 8 is fixed to the printed circuit board 3 by soldering pins thereof 
and it forms the arithmetic operation unit in the block diagram of FIG. 2. 
Electronic parts 9 and 10 such as a resistor and capacitor are also 
connected to the printed circuit board 3. 
Numeral 6 denotes a liquid crystal display which is electrically connected 
to the connecting pattern 3d on the printed circuit board 3 through a 
press-contact type connector 7. 
Displaced under the printed circuit board 3 is a reinforcing plate 5 made 
of rigid material, which covers the back surface of the desk-top 
calculator and is fixedly bonded to the printed circuit board 3 and the 
periphery of the lower surface of the frame 2 to assure the strength of 
the entire desk-top calculator. The printed circuit board 3 is a single 
side printed circuit board and has no circuit pattern on the side bonded 
with the reinforcing plate 5. Accordingly, the material of the reinforcing 
plate 5 may be a highly rigid metal. Numeral 11 denotes a polarizing 
plate. 
By stacking various parts as shown in FIG. 5, a very thin desk-top 
calculator can be constructed. Sectional views of the stacked key input 
unit and display are shown in FIGS. 6 and 7. 
As shown in FIG. 6, the key inputting stationary contact 3b faces the 
bottom of the recess 1b of the dome 1a of the thin metal plate 1 
insert-molded in the frame 2, with a clearance corresponding to the key 
stroke being left therebetween. The top of the dome 1a contacts the lower 
surface of the cover sheet 4. 
The pattern 3a which is a portion of the key signal line contacts the 
contact blocks B.sub.1 -B.sub.8 at the folded connecting area 1f. 
Therefore, the recess 1b is always in contact with the selected key signal 
line. 
As a result, when the cover sheet 4 is depressed by a finger in the 
direction of an arrow shown in FIG. 6, the cover sheet 4 is flexed, the 
upper surface of the dome 1a is pressed, the recess 1b descends and 
compression force is applied to the periphery of the dome 1a. As a result, 
the pressing load increases as the pressing stroke increases. When the 
cover sheet 4 is further depressed, the peripheral edge of the dome 1a 
sinks downward and is flexed. Thus, the compression force changes to a 
tensile force and the pressing resistance abruptly decreases. Accordingly, 
to compare with the prior art key input unit which uses a rubber material 
for key switches, definite pressing feeling (click feeling) is obtained 
with a shorter stroke. 
The bottom of the recess 1b contacts the key inputting stationary contact 
3b so that the key input is attained. 
The dome 1a of the thin metal plate 1 insert-molded in the frame 2 provides 
a sufficient resiliency to convey the depression force from the key input 
area of the cover sheet 4 to the printed circuit board 3 with the click 
feeling so that excellent key input is attained. 
FIG. 7 shows a packaged structure of the display 6. As shown in FIG. 3, the 
periphery 1hh of the opening 1h of the metal plate 1 which serves to hold 
the display 6 projects from the frame body 2. This projected area 1hh 
holds the display 6. The display 6 is connected to the pattern 3d of the 
printed circuit board 3 through the conductive connector 7. 
A packaged structure of the solar cell 12 for supplying a power to the 
arithmetic operation unit is shown in FIG. 8. 
The peripheral projected area 1ii of the opening 1i of the thin metal plate 
1 which serves to hold the solar cell 12 is contracted to form a step of a 
predetermined width as shown in FIG. 1. The amorphous solar cell 12 is 
held in the contracted area 1k of the opening 1i. The window area 4b of 
the cover sheet 4 facing the opening 1i has no print applied thereon so 
that external light is transmitted to the solar cell 12, which generates 
an electromotive force, which in turn is supplied to the conductive 
pattern on the printed circuit board 3 through the connector 13. 
Unlike the primary cell commonly used in the prior art, the solar cell 12 
can be used semipermanently and need not be exchanged. Therefore, the 
electronic equipment of the invention may be packed in a sealed condition. 
In accordance with the present embodiment, the number of parts is 
significantly reduced, the assembling work is easy and the cost is 
significantly reduced. 
The surface of the desk-top calculator has no unevenness due to the key 
tops and a flat card type thin desk-top calculator is provided. It can be 
hermetically sealed for water proof and dust proof, and a portable 
electronic equipment which is not restricted by an environment of use is 
provided. 
Since the metal plate is inserted over a substantially entire area of the 
frame 2, the thermal deformation and the poor mechanical strength which 
are weak points of the high molecular material are compensated for and the 
strength of the entire desk-top calculator is enhanced. 
Since the parts exposed to the outer surface of equipment such as a 
desk-top calculator are plate-like parts like the display and solar cell, 
the supply of the parts is easy. They do not need locking parts such as 
bolts and nuts and hence they can be assembled with an automatic assembly 
line. 
As to the structure of the key input unit, the movable contacts formed by 
the domes of the thin metal plate are used in spite of the thin desk-top 
calculator structure. Therefore, clear click feeling is attained and the 
end of the key input can be sensed by the click feeling through the 
finger. Accordingly, a high operability of keyboard is provided. 
The key inputting movable contacts are divided into blocks one for each key 
input signal and they are merely contacted to the stationary contacts on 
the printed circuit board. Accordingly, unlike a conventional bridge 
system in which the movable contact shorts two key inputting signal 
patterns on the printed circuit board, the present system can simplify the 
pattern on the printed circuit board and the pattern can be formed on a 
single side of the printed circuit board. Accordingly, the present system 
can input key signals more exactly than the bridge system. 
The electronic parts such as the display and solar cell packaged in the 
frame are fixed by the thin metal plate inserted in the frame. Thus, the 
strength is assured by the plate thickness which cannot alone be attained 
by a high molecular material such as synthetic resin. 
The present invention is not limited to the above embodiment. While the 
domes 1a and the recesses 1b are integrally formed with the thin metal 
plate 1 in the illustrated embodiment, the domes 1a and the recesses 1b 
may be omitted. In this case, holes are formed in the thin metal plate 1 
at the positions corresponding to the domes 1a and the recesses 1b while 
leaving disc-shaped projections projecting from the frame body, and 
movable contacts made of conductive rubber are mounted on the projections 
so that the disc-shaped projections hold the movable contacts and serve as 
contacts electrically connected to the movable contacts. In any case, the 
thin metal plate 1 should function as the contacts which are portions of 
the closing means for closing the key input circuit on the printed circuit 
board 3. 
The reinforcing plate 5 is not always necessary. When it is omitted, the 
thin metal plate 1 of the frame 2 may serve as the reinforcing plate. 
Therefore, the thickness of the metal plate may be appropriately changed. 
While the thin metal plate is insert-molded to the frame body in the 
illustrated embodiment, the metal plate may be coated with insulative 
adhesive material to form the frame. 
The present invention is also applicable to equipment other than desk-top 
calculators, such as teaching machines and game machines. What is claimed 
is: