Envelope opener

An envelope opener having a pair of entries in its opposite sides through which an envelope may enter the opener from either side to have its head automatically cut as it passes through the opener, comprises: cutters driven by a reversible electric motor; a lane for guiding the envelope, interrupted by the cutters; a pair of bar-type sensors swingably mounted crossing the lane, each being positioned in opposite sides of the cutters; a link connecting the sensors with each other to swing the sensors in synchronism when one is swung by an envelope passing through the lane; and contact assemblies coupled with the sensors, one of the assemblies being operated by the of the sensors to establish rotational directions of the motor and the cutters when the envelope entered the opener from either side swings one of the sensors to bring the other through the link into a position where the other of the contact assemblies coupled with the other of the sensors remains opened.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an envelope opener, and more particularly 
to a double entry type envelope opener provided with a pair of entries in 
opposite ends of an envelope guide lane for guiding the head or closure 
flap portion of an envelope to be cut, through which entries the head of 
the envelope may enter the guide lane of the opener to have its head or 
closure flap portion automatically cut as the latter passes through the 
guide lane of the opener. 
2. Description of the Prior Art 
A conventional envelope opener is a single-entry type opener provided with 
an entry in an end of the envelope guide lane, through which entry the 
head or closure flap portion of the envelope may enter the guide lane of 
the opener to have its head or closure flap portion automatically cut as 
it passes through the guide lane. Such conventional opener has a 
construction in which rotary disc blades are rotated by an electric motor 
in a predetermined single direction to permit the head or closure flap 
portion of the envelope to enter the guide lane of the opener through such 
entry of the guide lane, whereby the head of the envelope is automatically 
cut as the latter passes through the guide lane of the opener in a 
predetermined single direction. 
In the conventional single-entry type envelope opener, as described above, 
since the rotary disc blades are rotated in the predetermined single 
direction to automatically cut the head or closure flap portion of the 
envelope as the latter passes through the guide lane of the opener in the 
predetermined single direction, it is not possible for the envelope to 
enter the opener theough the other side of the opener so as to pass 
through the opener in a direction counter to the above predetermined 
single direction, and, therefore, in this respect, the conventional 
envelope opener is poor in easiness for use. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide a double-entry type 
envelope opener provided with a pair of entries in its opposite sides 
through which entries the head or closure flap portion of an envelope may 
enter an envelope guide lane of the opener from either side to have its 
head automatically cut as the latter passes through the guide lane of the 
opener in either direction . 
The envelope opener of the present invention is provided with such a 
reversible electric motor and a pair of rotary disc blades driven thereby 
that are able to automatically change their rotational direction according 
to envelope's entry direction to the opener without employing a 
specialized misoperation prevention system, and accordingly the opener of 
the present invention permits the envelope to enter the guide lane of the 
opener from either side entry thereof so as to pass therethroug in either 
direction, whereby the head of the envelope may be automatically cut as 
the latter passes through the guide lane of the opener. Thus, there can be 
provided such improved double-entry type opener that is very easy for use. 
The above object of the present invention is accomplished by providing: 
A double-entry type envelope opener provided with a pair of entries in its 
opposite sides through which an envelope may enter the opener from either 
side to have its head automatically cut as the latter passes through the 
opener, comprising: 
a reversible electric motor; 
a pair of rotary disc blades driven by the reversible electric motor, the 
rotary disc blades being vertically arranged; 
a guide lane horizontally extending for guiding the envelope therethough, 
the guide lane being centrally interrupted by the pair of rotary disc 
blades; 
a pair of bar-type swingable sensors vertically mounted on the guide lane 
so as to cross the latter, the bar-type swingable sensors being positioned 
in opposite sides of the pair of rotary disc blades; 
a link connecting the pair of bar-type swingably sensors with each other to 
deive one of the bar-type swingable sensors on synchronism with the other 
when the one is swinged by an envelope passing through the guide lane; and 
a pair of contact assemblies coupled with the pair of bar-type swingable 
sensors, one of the contact assemblies being operated by the one of the 
bar-type swingable seneors to establish rotational directions of the 
reversible electric motor and the rotary disc blades when the head of an 
envelope enters the opener from either entry and passes the guide land in 
either direction to swing the one of the bar-type swingable sensors, which 
in turn moves the other through the link into a position where the other 
of the contact assemblies coupled with the other of the bar-type swingable 
sensors remains opened or turned off.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
The present invention will now be described in detail, by way of example, 
with reference to the accompanying drawings in which like reference 
numerals apply to similar parts throughout the several views. 
In FIG. 4, the reference numeral 1 denotes an envelope provided with a head 
or closure flap portion 1a. 
A double-entry type envelope opener of the present invention is provided 
with a pair of entries 3a in its opposite sides through which an envelope 
1 may from either side enter a horizontally extending envelope guide lane 
3 to have its head or closure flap portion 1a automatically cut as it 
passes therethrough. As is clear from FIG. 4, the opposite entries 3a of 
the opener are outwardly spreaded inlet openings of the horizontally 
extending guide lane 3 which may horizontally guide the envelope 1 passing 
therethrough in either direction. The guide lane 3 is fixedly mounted in a 
front portion of a split housing 2 of the opener. 
The envelope opener of the present invention further comprises: a 
reversible electrec motor M; a pair of rotary disc blades 4.sub.1, 4.sub.2 
which may be rotatably driven in either direction by the reversible 
electric motor M, the rotary disc blades 4.sub.1, 4.sub.2 being vertically 
arranged; a pair of bar-type swingable sensors 5 vertically, symmetrically 
mounted on the guide lane 3 so as to cross the latter, the bar-type 
swingable sensors 5 being positined in opposite sides of the pair of 
rotary disc blades 4.sub.1, 4.sub.2 so as to detect or to be swinged by 
the envelope 1 passing through the guide lane 3 in either direction, 
whereby controlling rotational direction of the motor M depending on from 
which entry the envolope enters to the opener; a link 7 connecting the 
pair of bar-type swingable sensors 5 with each other to drive one of them 
in synchronism with the other when the one is swingably moved by the 
envelope 1 passing through the guide lane 3; and a pair of contact 
assemblies 6.sub.1, 6.sub.2 of double-throw switch type coupled with the 
pair of bar-type swingable sensors 5, one of the contact assemblies 
6.sub.1, 6.sub.2 being operated by the one of the bar-type swingable 
sensors 5 so as to establish a rotational direction of each of the 
reversible electric motor M and the rotary disc blades 4.sub.1, 4.sub.2 
when the head or closure flap portion 1a of the envelope 1 enters the 
guide lane 3 from either entry 3a and passes therethough in either 
direction to swingably move the one of the bar-type swingable sensors 5, 
which in turn moves the other through the link 7 into a position in which 
the other of the contact assemblies 6.sub.1, 6.sub.2 coupled with the 
other of the bar-type swingable sensors 5 remains opened or turned off. 
As shown in FIGS. 1 to 4, the split housing 2 is made of plastics, and 
formed into a flat shape with a portable size to enable the user to carry 
it in his hand. The split housing 2 may consist of two pieces. 
On the other hand, the guide lane 3 is formed in a horizontally elongated 
form in the interior of the front portion of the housing 2. Namely, as 
shown in FIG. 4, the guide lane 3 is defined by a pair of horizontally 
elongated walls 8 which are vertically oppositely disposed from each 
other. As described above, the opposite end portions, or entries of the 
guide lane 3 are formed into the outwardly spreaded openings 3a for 
facilitating the envelope 1 to enter from either side of the opener. 
When the head or closure flap portion 1a of the envelope 1 enters the guide 
land 3 of the opener to swing the bar-type swingable sensors 5, the 
sensors 5 operate the contact assemblies 6.sub.1, 6.sub.2 to establish a 
rotational direction of the motor M. As shown in FIGS. 3, 4 and 6, each of 
the bar-type swingable sensors 5 is provided with a substantially 
sleeve-like bearing portion 5a in its upper end. In each bearing portion 
5a is rotatably inserted a supporting pin 9 which is spaced apart from the 
guide lane 3 and extends horizontally in a direction perpendicular to the 
longitudinal direction of the guide lane 3, whereby each bar-type 
swingable sensor 5 may swing in a plane parallel to the longitudinal 
direction of the guide lane 3. As shown in FIG. 4, during non-use of the 
envelope opener, the bar-type swingable sensors 5 are substantially 
perpendicular to the longitudinal axis of the guide lane 3, and parallelly 
spaced from each other. 
On the other hand, the link 7 connecting the sensors 5 with each other is 
provided with a pair of elongated slits 7a on its opposite end portions. 
In each slit 7a is slidably mounted an axle 5b which forms a projection 
provided in a front surface of a lower half portion of each sensor 5. 
As described above, the link 7 forms a connecting means for connecting the 
bar-type sensors 5 with each other. Consequently, when either sensor 5 is 
swinged by the head or closure flap portion 1a of the envelope 1 entered 
the guide lane 3 through either entry 3a thereof, the thus firstly swung 
sensor 5 swings in turn the other sensor 5 through the link 7 in 
synchronism therewith, whereby one of the contact assemblies 6.sub.1, 
6.sub.2 coupled with the firstly swung sensor 5 is closed or turned on to 
establish rotational directions of the motor M and the rotary disc blades 
4.sub.1, 4.sub.2 driven thereby. At this time, the firstly swung sensor 5 
also brings, through the link 7, the other contact assembly 6.sub.1 or 
6.sub.2 coupled with the other sensor 5 into a position where the other 
contact assembly 6.sub.1 or 6.sub.2 remains opened or turned off. After 
passing of the head 1a of the envelope 1 through the guide lane 3 of the 
opener, the bar-type swingable sensors 5 return in synchronism with each 
other by gravity to their neutral positions where they are substantislly 
perpendicular to the longitudinal axis of the guide lane 3. 
As shown in FIG. 4, the contact assemblies 6.sub.1, 6.sub.2 coupled with 
the bar-type swingable sensors 5 are mounted in an upper front portion of 
the interior of the split housing 2. As is clear from FIGS. 6 to 8, each 
of the contact assemblies 6.sub.1, 6.sub.2 serves as a double-throw switch 
for establishing a rotational direction of the reversible electric motor 
M, and is constructed of moving-contact members 10, 10' and substantially 
stationary-contact members 11, 11', respectively laterally separated by a 
partition plate 27, as shown in FIG. 4. In each of the contact assemblies 
6.sub.1, 6.sub.2, the moving-contact members 10, 10' and the substantially 
stationary-contact members 11, 11' are constructed of resilient and 
electrically-conductive metallic leaf springs, and vertically spaced apart 
from each other as shown in FIGS. 6 to 8. It is to be understood that 
reference numerals 10 and 11 denote positive side and 10' and 11' do 
negative side, respcetively. 
As is clear from FIGS. 6 to 8, each end-portion of the moving-contact 
member 10, 10' are fixedly sandwiched between an upper-holding plate 12 
and a middle-holding plate 13, while each end-portion of the substantially 
stationary-contact members 11, 11' are fixedly sandwiched between the 
middle-holding plate 13 and a lower-holding plate 14. These holding plates 
12, 13, 14 are fixedly mounted in a front portion of the interior of the 
split housing 2 for facilitating installation of the contact members 10, 
10', 11, 11'. The other end-portion of each of the contact members 10, 
10', 11, 11' forms a free end to serve as an electrical contact point. A 
partition plate 15 fixed to the split housing 2 is interposed between the 
moving-contact members 10, 10' and the substantially stationary-contact 
members 11, 11' to prevent the contact members 10, 10' 11, 11' from being 
accidentally brought into contact with each other. 
In FIGS. 4 and 6 to 8, the bar-type swingable sensors 5 and the contact 
assemblies 6.sub.1, 6.sub.2 coupled therewith will be now further 
described in detail with respect to construction. The reference numeral 5c 
denotes a push projection provided in an upper end portion of each 
bar-type swingable sensor 5. In the pair of the sensors 5, as shown in 
FIG. 6, the push projections 5c thereof symmetrically extend outward or in 
opposite directions to each other. In operation, when the head or closure 
flap portion 1a of the envelope 1 entered the guide lane 3 of the opener 
swings either sensor 5, the remaining sensor 5 is also swung in 
synchronism with thus firstly swung sensor 5 through the link 7, however 
the only firstly swung sensor 5 causes its push projection 5c to push the 
moving-contact member 10 downward, whereby the push projection 5c of the 
firstly swung sensor 5 is brought into an electrical contact with the 
corresponding substantially stationary-contact members 11, 11' to close or 
turn on eithr contact assembly 6.sub.1 of 6.sub.2 In the case of FIG. 7, 
the contact assembly 6.sub.1 is closed or turned on, while the other 
contact assembly 6.sub.2 remained opened or turned off so that a 
rotational directon of the reversible electric motor M is established by 
the contact assembly 6.sub.1 in the case of FIG. 7. 
As shown in FIG. 4, the motor M is laterally mounted in the split housing 2 
to enable the split housing 2 to assume a flat shape. 
As is clear from FIG. 4, the pair of rotary disc blades 4.sub.1, 4.sub.2 
slightly overlapped each other are vertically arranged in the vicinity of 
a center line or longitudinal axis of the guide lane 3. An outer 
peripheral edge portion of each of the rotary disc blades 4.sub.1, 4.sub.2 
is formed into a sawtooth 4.sub.a. 
As shown in FIG. 5, the power produced in the motor M is transmitted to the 
rotary disc blades 4.sub.1, 4.sub.2 through a transmission mechanism 16. 
As is clear from FIG. 5, the transmission mechanism 16 of the envelope 
opener of the present invention is constructed of: a worm 18 fixedly 
mounted on a driving shaft 17 of the reversible motor M; a worm gear 19 
meshed with the worm 18; a first small gear 20 fixedly and coaxially 
mounted on an axle of the worm gear 19; a first intermediate gear 21 
meshed with the first small gear 20; a second small gear 22 fixedly and 
coaxially mounted on an axle of the first intermediate gear 21; a second 
intermediate gear 23 meshed with the second small gear 22; a third small 
gear 24 fixedly and coaxially mounted on an axle of the second 
intermediate gear 23; a third intermediate gear 25 meshed with the third 
small gear 24; and a final gear 26 meshed with the third intermediate gear 
25, the final gear 26 being similar in diameter to the third intermediate 
gear 25. 
In FIG. 4, the reference numeral 28 denotes a substantially L-shaped cover 
plate for covering a front area of each of the contact assemblies 6.sub.1, 
6.sub.2,the cover plate 28 is detachably mounted on the split housing 2 by 
means of a screw 29. 
In FIG. 1, the reference numeral 30 denotes a battery holder mounted in a 
rear portion of the split bousing 2. In the battery holder 30 are received 
a suitable number of dry cells or storage cells 31. The battery holder 30 
is closed with a lid 32 detachably mounted on the rear portion of the 
split housing 2. 
Now, operation of the envelope opener of the present invention will be 
described in detail. 
In use, the user holds the opener or split housing 2 in his hand, and, for 
example as shown in FIG. 7, inserts the head or closure flap portion la of 
the envelope 1 into the guide lane 3 of the opener through the left entry 
3a of the guide lane 3. 
As a result, when the inserted head or closure flap portion 1a of the 
envelope 1 pushes the left sensor 5 rightward as shown in FIG. 7, both 
sensors 5 are swinged rightward in synchronism with each other through the 
link 7 to rotate around their supporting pins 9 counterclockwise as shown 
in FIG. 7. 
Consequently, the push projection 5c provided on the upper-end portion of 
the left sensor 5 pushes the left moving-contact members 10, 10' downward 
to bring them into electrical contact with the left substantially 
stationary-contact members 11, 11', whereby the left contact assembly 
6.sub.1 is closed or turned on to establish a rotational direction of the 
reversible electric motor M. In this case of FIG. 7, the driving shaft 17 
of the motor M rotates clockwise so that, as shown in FIG. 5, the power of 
the motor M is transmitted to the rotary disc blades 4.sub.1, 4.sub.2 
through the worm 18, worm gear 19, first small gear 20, a first 
intermediate gear 21, second small gear 22, second intermediate gear 23, 
third small gear 24, third intermediate gear 25 and the final gear 26 or 
the transmission mechanism 16. Since the third intermediate gear 25 is 
similar in diamiter to the final gear 26 meshed therewith, the final gear 
26 rotates in a direction counter to that of the third intermediate gear 
25. On the other hand, as is clear from FIG. 5, an upper rotary disc blade 
4.sub. 2 is fixedly and coaxially mounted on an axle of the final gear 26, 
while a lower rotary disc blades 4.sub.1 is fixedly and coaxially mounted 
on an axle of the third intermediate gear 25. Therefore, the rotary disc 
blades 4.sub.1, 4.sub.2 are rotated in opposite directions to each other 
by the motor M when the head or closure flap portion 1a of the envelope 1 
is inserted into the guide lane 3 of the opener by the user, which 
enhances cutting operation of the rotary disc blades 4.sub.1, 4.sub.2 with 
respect to the envelope 1. Namely, as shown in FIG. 7, the inserted head 
1a of the envelope 1 is positively and continuously cut by the rotary disc 
blades 4.sub.1, 4.sub.2 as the head or closure flap portion 1a of the 
envelope 1 passes through the guide lane 3 of the opener. 
Since the left sensor 5 is connected with the right sensor 5 through the 
link 7 in operation, the right sensor 5 per se not pushed by the envelope 
1 is also swung rightward through the link 7 in synchronism with the left 
sensor 5 to cause its push projection 5c to separate upward from the right 
woving-contact member 10 so that the right contact assembly 6.sub.2 
remains opened or turned off, whereby the right contact assembly 6.sub.2 
is prevented from being accidentally closed or turned on. 
In opeartion of the envelope opener of the present invention, since the 
head la of the envelope 1 passing through the guide lane 3 of the opener 
continuously pushes the left sensor 5 until it is completely cut, the 
opener of the present invention may cut envelopes of various sizes and 
various thicknesses. 
In addition, in the envelope opener of the present invention, since the 
rotary disc blades 4.sub.1, 4.sub.2 rotate in opposite directions to each 
other as described above and brought into a frictional contact with the 
head or closure flap portion 1a of the envelope 1, these rotary disc 
blades 4.sub.1, 4.sub.2 positively pull the head or closure flap portion 
1a of the envelope 1 and cut it. 
Furthermore, as shown in FIG. 4, which the envelope opener of the present 
invention, a horizontal distance L between a vertical rear wall of the 
guide lane 3 and a rear surface of the upper rotary disc blade 4.sub.2 
corresponds to a cutting width L.sub.1 of the head or closure flap portion 
1a of the envelope 1, but it is possible to easily control the cutting 
width L.sub.1 of the head 1a of the envelope 1 by controlling the above 
horizontal distance 1. 
When the head 1a of the envelope 1 has been completely cut, the bar-type 
swingable sensors 5 and the link 7 return to their initial positions by 
gravity to release the left moving contact members 10, 10' from the left 
substantially stationary-contact members 11, 11'. As a result, the left 
moving-contact members 10, 10' return to their initial positions by their 
resiliency to bring the left contact assembly 6.sub.1 into a turned-off 
condition, whereby operation of the motor M is stopped, and, therefore 
operations of the rotary disc blades 4.sub.1, 4.sub.2 are also stopped. 
Consequently, after completion of cutting operation of the head 1a of the 
envelope 1, the bar-type swingably sensors 5 and left contact assembly 
6.sub.1 returns to their initial positions, so that the sensors 5 are 
positioned to cross the guide lane 3 as shown in FIG. 6. 
Now, cutting operation of the head or closure flap portion 1a of the 
envelope 1 in the case of FIG. 8 will be described in detail. 
As shown in FIG. 8, when the head or closure flap portion 1a of the 
envelope 1 is inserted into the guide lane 3 of the opener through the 
right entry 3a, the right sensor 5 is swung leftward by the head 1a of the 
inserted envelope 1, so that both sensors 5 swing around the supporting 
pins 9 clockwise to cause the push projection 5c of the right sensor 5 to 
push the right moving-contact members 10, 10' downward. Accordingly, the 
right moving-contact members 10, 10' are brought into an electrical 
contact with the right substantially stationary-contact members 11, 11' to 
close or turn on the assembly 6.sub.2, whereby a rotational direction of 
the reversible electric motor M is established. 
As a result, in the case of FIG. 8, the motor M rotates in a direction 
counter to that of the motor M in the case of FIG. 7, so that the gears 
25, 26 connected with the rotary disc blades 4.sub.1, 4.sub.2 also rotate 
in directions counter to those of the gears 25, 26 in the case of FIG. 7. 
Consequently, the head 1a of the envelope 1 is brought into frictional 
contact with the rotary disc blades 4.sub.1, 4.sub.2 and positively cut 
thereby continuously as it passes through the guide lane 3 leftward. 
In the case of FIG. 8, since the head 1a of the envelope 1 continuously 
swings the right seneor 5 until it is completely cut, the right contact 
assembly 6.sub.2 is continuously closed or turned on so as to continuously 
rotate the rotary disc blades 4.sub.1, 4.sub.2 in directions shown by 
arrows in FIG. 8. On the other hand, at this time, since the push 
projection 5c of the left sensor 5 is separated upward from the left 
moving-contact members 10, 10', there is no fear that the left 
moving-contact members 10, 10' are accidentally brought into eletrical 
contact with the left substantially stationary-contact members 11, 11'. 
After completion of the cutting operation of the head 1a of the envelope 1, 
since the right sensor 5 is released from the head 1a of the envelope 1, 
it returns to its initial position by gravity, with the push projection 5c 
thereof also returning to its initial position by the resiliency of the 
right moving-contact members 10, 10' to enhance the gravity return of the 
right sensor 5. At this time, the left sensor 5 and the link 7 connected 
to the right sensor 5 also return to their initial positions by gravity, 
so that the right contact assembly 6.sub.2 is opened or turned off to stop 
the motor M in operation. Consequently, the rotary disc blades 4.sub.1, 
4.sub.2 are also stopped in operation. When the bar-type sensors 5 return 
to their initial positions, they again cross the guide lane 3 as shown in 
FIG. 6. 
Cutting operation of the head 1a of the envelope 1 inserted into the guide 
lane 3 of the opener through the right entry 3a of the guide lane 3 as 
shown in FIG. 8 is completed as described above. 
Incidentally, in the above embodiment of the envelope opener of the present 
invention, it is also possible to employ such other means in place of the 
push projections 5c provided in the upper-end portions of the bar-type 
swingable sensors 5, that may be a suitable engaging means constructed of 
projections and corresponding concave members, a magnetic means, a 
frictional means or the like. 
In addition, in the envelope opener of the present invention, if necessary, 
the number of the sensors 5 may be one, and the sensors 5 may be arranged 
horizontally.