Binder

A binder is provided for joining a plurality of objects together with a binding string. The binder includes a base member having a recess for receiving the objects. Structure for feeding the binding string is disposed behind the recess. A hook-shaped hand is provided for guiding the binding string around the objects and for causing a loose end of the binding string to turn back in a U shape while pressing the binding string against the objects to be bound, and for twisting the loose end of the binding string with another portion of the binding string to perform binding. The hook-shaped hand includes a slide base plate capable of moving backward and forward relative to the recess, a hook-shaped curved member rotatably coupled to the slide base plate and movable backward and forward in response to movement of the slide base plate, and a rotation mechanism for engaging and thereby rotating the hook-shaped curved member toward the recess in synchronized relation with forward movement of the slide base plate.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to a binder and more particularly to a binder for 
binding rod-like objects by means of a string-like object (generally 
referred to as a binding string) such as a metallic wire that can be 
fastened. 
2. Description of the Prior Art 
A known conventional binder brings a continuous binding string around the 
opening or upper part of a plastic bag in a U shape, cuts the string to a 
suitable length, and fastened by twisting both ends of the string. 
As one of this type of conventional binder, one is disclosed in a Japanese 
Unexamined Patent Application (Tokkai) Hei 2-166019. 
The binder shown in the above-mentioned application has a girdling 
mechanism for bringing a metallic wire around rod-like objects held in a 
recess, and comprising a feeder chain made up of trapezoidal feeder blocks 
connected in series along their longer sides, a hand member secured to the 
projecting end of the feeder chain and having a wire holding mechanism at 
the end thereof, and a guide mechanism for causing the metallic wire to 
girdle the rod-like objects held in the recess by moving the feeder chain 
from one side of the recess to the other. 
In the above constitution, when the guide mechanism causes the feeder chain 
to run and the hand member moves from one side to the other of the recess, 
the trapezoidal feeder blocks tend to come into contact with their side 
surfaces each other because of tension produced when the metallic wire is 
fed out. As a result, the feeder chain goes around the rod-like objects. 
SUMMARY OF THE INVENTION 
The above binder has disadvantages of increased number of components and 
increased number of man-hours in manufacture because a number of feeder 
blocks are joined together to form the feeder chain. 
In view of the disadvantages described above, the object of this invention 
is to provide a binder comprising a reduced number of components resulting 
in a reduced number of man-hours in manufacture. 
To accomplish the above object, the binder of this invention having a 
recess for receiving objects to be bound, feeds out a binding string from 
behind the recess, guides the string around the objects to be bound by 
means of a hook-shaped hand and causes the front end of the string to turn 
back in a U shape while pressing the string against the object to be 
bound, and twists the front end of the string around other portion of the 
string being fed out to perform binding, with the hand comprising; a slide 
base plate capable of moving back and forth relative to the recess, a 
hook-shaped curved member rotatably supported in front of the slide base 
plate, and a rotation mechanism for rotating the curved member toward the 
recess as the slide base plate engaging with the curved member for 
synchronous rotation moves forward. 
In this type of invention, when the slide base plate moves forward, the 
rotation mechanism causes the curved member supported for rotation 
relative to the slide base plate to rotate toward the recess. As a result, 
the curved member rotates along a small radius to cause the binding string 
to encircle the circumference of the objects to be bound. 
As described above, this invention provides a binder of a compact size with 
a reduced number of components and simplified constitution because, when 
the binding string is guided and pressed by the hook-shaped hand against 
the circumference of the objects to be bound, the slide base plate moves 
forward while causing the curved member to turn with a very small radius. 
Another feature of the above binder of this invention is that the slide 
base plate, while swinging about a rotary shaft, moves back and forth 
relative to the recess. 
In such an arrangement, since the slide base plate moves back and forth in 
a radial direction relative to the recess while swinging about the rotary 
shaft, accuracy is improved with a simple structure. 
Still another feature of the above binder of this invention is that the 
rotation mechanism is constituted to be supported for rotation on the 
slide base plate in interlocked motion with the curved member, and to 
rotate the curved member when the slide base plate moves back and forth. 
In such an arrangement, the rotary mechanism, while rotating on the slide 
base plate, causes the curved member to rotate when the slide base plate 
moves back and forth. 
Thus, this invention simplifies the constitution of the binder since the 
the rotary mechanism, and while rotating along with the back and forth 
movement of the slide base plate, causes the curved member to rotate, 
requiring no additional drive source. 
Still another feature of the binder of this invention is that the slide 
base plate is constituted to swing together with a rotating drive cam by 
the engagement between a driven cam and a driven cam. 
In such an arrangement, the slide base plate is moved back and forth by the 
rotary movement of the drive cam. 
Thus, this invention makes it easy to move the slide base plate back and 
forth by means of the drive with a simple structure.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Preferred embodiments of the invention will be hereinunder described in 
reference to the appended drawings. 
FIG. 1 is a right side view of a binder as an embodiment of the invention 
with its protective cover removed. FIG. 2 is a plan view of the binder. 
FIG. 3 is a front view of the binder. The binder of the invention 
comprises two base plates (10a, 10b) held with a distance from each other 
with each plate having a recess at its end, and a drive shaft (15) passing 
through the base plates, and the base plates are driven by a cam (15b) 
secured to the drive shaft. The binding string is made of a metallic wire 
coated with a plastic film of a band shape. 
FIG. 4 schematically shows the state of the two base plates (10a, 10b). A 
binding string can be passed between upper and lower spacers (11a, 11b) 
disposed with a small gap from each other. The spacers (11a, 11b) are 
formed at their rear portions with recesses for receiving two sets of feed 
rollers. In the front side recesses, drive rollers (12a, 12b) are 
received. In the rear side recesses, reverse movement check rollers (13a, 
13b) are received. Shafts (12a1, 13a1) of the upper side feed rollers 
(12a, 13a) are supported to be movable within slots (10a1, 10b1) formed in 
the base plates (10a, 10b) so that when the upper side feed rollers (12a, 
13a) move upward they come apart from the lower side feed rollers (12b, 
13b). Of the lower rollers, only the shaft (13b1) of the rear side roller 
(13b) is provided with a one-way clutch to permit only counterclockwise 
rotation. As shown in FIG. 5, the shaft (12b1) of the front side feed 
roller (12b) passes through the right side base plate (10b). A gear (12b2) 
is secured to the end of the shaft (12b1). The gear (12b2) is capable of 
engaging with a partially cogged gear (15a) secured to the drive shaft 
(15) so that the feed roller (12b) together with the shaft (12b1) is 
rotated when the drive shaft (15) rotates in the clockwise direction and 
the cogged portion (15a1) of the partially cogged gear (15a) engages with 
the gear (12b2). The drive shaft (15) is also provided with a feed amount 
regulating cam (15b) to be capable of coming into contact with a regulator 
plate (14a) of a release arm (14) disposed adjacent to a convex portion 
(15b1) of the cam (15b). 
As shown in FIGS. 6 and 7, the release arm (14) comprises two identical 
plate members (14b1, 14b2) secured with a distance from each other with a 
regulator plate (14a) disposed to be slidable on the top surface, with its 
front end supported to be rotatable relative to the base plate (10b), and 
with its rear end supporting the shaft (12a1) of the feed roller (12a). 
The regulator plate (14a) is provided with a projection (14a1) projecting 
toward the drive cam (15b). A tightening bolt (14c) is disposed to pass 
through the regulator plate (14) and an elongate hole (14b2a) of the right 
side plate member (14b2) so as to engage with a nut on the back side. Both 
plate members (14b1, 14b2) are provided with horizontally projecting 
manual drive bars (14d1, 14d2), with the end of the manual drive bar 
(14d2) engaging with a spring (14e) so as to exert a clockwise force on 
the release arm (14). A release lever (16) supported to be rotatable 
relative to the base plate (10b) has three projections (16a, 16b, 16c) 
with one of the projections (16a) disposed at a lower portion of rotation 
range of the manual drive lever (14d1). The projection (16b) extends 
outside the the base plate (10b) and the projection (16c) supports a shaft 
(13a1) of the feed roller (13a). The release lever (16) is urged 
counterclockwise by a spring (16b) so that the projection (16c) presses 
the feed roller (13a) against the feed roller (13b) by way of the rotary 
shaft (13a1). When the projection (16b) is pressed to rotate clockwise, 
the projection (16c) causes the feed roller (13a) to moves away from the 
feed rollers (13b), and the projection (16a) comes into contact with the 
manual drive lever (14d1) of the plate member (14b1) to rotate clockwise, 
and causes the feed roller (12a) supported on the release arm (14) to move 
away from the feed roller (12b). 
First the release lever (16) is rotated counterclockwise to separate the 
upper side feed rollers (12a, 13a) from the lower side rollers (12b, 13b) 
so that a binding string enters from behind and between the upper and 
lower spacers (11a, 11b). When the front end of the binding string reaches 
the front end of the lower spacer (11b), the release lever (16) is 
released, and the upper side feed rollers (12a, 13a) comes down to squeeze 
the binding string in cooperation with the lower side feed rollers (12b, 
13b). When the partially cogged gear (15a) rotates together with the drive 
shaft (15) and the cogged portion (15a1) engages with the gear (12b2), the 
feed roller (12b) begins to rotate. Since the feed roller (12b) rotates 
counterclockwise, the binding string is fed forward. The binding string is 
fed while being pressed against the feed roller (12b) by the upper side 
feed roller (12a). When the feed amount regulation drive cam (15b) rotates 
and its projection (15b1) comes into contact with a projection (14a1) of 
the regulator plate (14a), the release arm (14) is raised to rotate 
counterclockwise, and the feed roller (12a) is separated from the feed 
roller (12b). As a result, the binding string is not fed even if the feed 
roller (12b) rotates. As described above, securing position of the 
regulator plate (14a) on the plate member (14b2) is adjustable using the 
tightening bolt (14c). If the regulator plate (14a) is secured to a 
relatively forward position on the plate member (14b2), the projection 
(15b1) comes into contact with the projection (14b1) at a relatively early 
timing, and the feed duration of the binding string becomes relatively 
shorter, and vice versa. FIG. 8 shows a state in which the drive shaft 
(15) has rotated and the projection (15b1) of the feed amount regulating 
drive cam (15b) has come into contact with the regulator plate (14a), and 
the feed roller (12a) has been separated from the feed roller (12b). 
In the left portion of the base plate (10a) as shown in FIG. 9, a manual 
drive cam (15c) is secured to the drive shaft (15). In the rear portion of 
the base plate (10a) is arranged a swing cam (17) supported to be 
rotatable relative to the base plate (10a). The swing cam (17) is formed 
with a recess (17a) surrounding the manual drive cam (15c) and having two 
projections (17a1, 17a2) at opposite positions each other with respect to 
the drive shaft (15). When the projection (15c1) of the manual drive cam 
(15c) comes into contact with one side and rejects it, the swing cam (17) 
rotates, and the other side moves toward the manual drive cam (15c). When 
the projection (15c) comes into contact with the opposite side, the swing 
cam (17) rotates toward opposite side. Thus, the swing cam (17) makes one 
cycle of back and forth swing as the manual drive cam (15c) makes one 
turn. 
A drive arm (18) is rotatably supported in front of the drive shaft (15), 
in the left portion of the base plate (10a), parallel to the base plate 
(10a), and connected to the swing cam (17) by way of a link (18a). The 
drive arm (18) is provided with support pins (18c1, 18c2) equally distant 
from the rotary shaft (18b). The support pins (18c1, 18c2) extend through 
the base plate (10a) up to a position between the base plates (10a, 10b). 
The base plate (10a) is formed with an arcuate slot (103a) along the 
rotary locus of the support pins (18c1, 18c2). 
As shown in FIGS. 10 and 11, an arcuate slide base plate (19) connected to 
the support pins (18c1, 18c2) is disposed between the base plates (10a, 
10b). The slide base plate (19) is formed with three through holes (19a1, 
19a2, 19a3) from front to rear, with the support pins (18c1, 18c2) 
inserted in the center and rear through holes (19a2, 19a3) respectively. 
Therefore, when the drive arm (18) connected to the swing cam (17) swings 
back and forth, the slide base plate (19) is caused to move back and forth 
along an arc by the support pins (18c1, 18c2). A root portion (20a) of a 
curved member (20) with a hooked end is rotatably supported in a through 
hole (19a1) formed in th front portion of the slide base plate (19). A 
back plate (21) having generally the same thickness and shape with those 
of the slide base plate (19) with the portion corresponding to the root 
portion (20a) removed is joined to the front end portion of the curved 
member (20). Part of the circumference of the root portion (20a) of the 
curved member (20) is formed with gear teeth (20a1). A rocker arm (22) 
with its front end having a gear portion (22a) for engagement with the 
gear (20a1) is supported for free rotation by the support pin (18c1) 
passing through the center through hole (19a2) in the slide base plate 
(19). A guide slide pin (22b) is erected at the right end of the rocker 
arm (22). As shown in FIG. 1, a guide slot (10b3) is formed in the base 
plate (10b) to receive the guide slide pin (22b) and permit it to slide 
along the slot. 
When the slide cam (17) swings back and forth, the drive arm (18) also 
swings back and forth, and the slide base plate (19) is driven along an 
arc by the support pins (18c1, 18c2). Along with this, the curved member 
(20) and the rocker arm (22) held at the front end of the slide base plate 
(19) also move back and forth. Since the guide slide pin (22b) of the 
rocker arm (22) moves back and forth along the drive guide slot (10b3) in 
the base plate (10b) in an arcuate path, the rocker arm (22) rotates about 
the center support pin (18c1) of the slide base plate (19), and causes the 
gear portion (22a) to engage with the gear (20a1) of the root portion 
(20a) of the curved member (20). Here, the rotation of the rocker arm (22) 
is clockwise and that of the curved member (20) is counterclockwise. As 
shown in FIG. 12, the curved member (20) moves forward while rapidly 
crossing the slots (10a4, 10b4) in the front portion of the base plates 
(10a, 10b) and turn around inward. When the curved member (20) moves in 
the opposite direction, its movement is opposite to the above. 
As shown in FIGS. 4 and 13, a cutter (23) comprises a cutter body (23a) 
held between the base plates (10a, 10b), a cutter blade (23b) held for 
movement within a small range at the front end of the cutter body (23a), a 
spring (23c) for urging the cutter blade (23b) counterclockwise, and a 
cutter drive arm (23d) secured to the rotary shaft of the cutter body 
(23a) on both sides of the base plate (10b). A U-shaped counter blade (24) 
is disposed with its opening directed upward along the continuous portions 
of the spacers (11a, 11b). The binding string is fed through the inside of 
the counter blade (24) and between the spacers (11a, 11b). 
A rotary cam (15e) is disposed to face the end of the cutter drive arm 
(23d) on the right of the base plate (10b). As shown in FIG. 14, when the 
rotary cam (15e) rotates, a projection (15e1) formed on the periphery 
comes into contact from under with the cutter drive arm (23d) to rotate 
the cutter drive arm (23d) counterclockwise. When the cutter drive arm 
(23d) rotates counterclockwise, the cutter blade (23b) moves up and down 
while its tip slides over the counter blade (24) to cut the binding string 
by a guillotine action in cooperation with the counter blade (24) when the 
cutter blade (23b) moves downward. Here, a holding plate (25) extending 
forward with its end bent downward is secured to the top surface of the 
cutter body (23a). 
The circumference of the rotary cam (15e) is provided, in addition to the 
projection (15e1), with a larger radius portion (15e2) and a smaller 
radius portion (15e3). As shown in FIG. 15, an arcuate row of teeth (15e4) 
extending downward are formed on the circumference of the smaller radius 
portion (15e3) so as to engage with a gear (26). The teeth row (15e4) is 
not formed in the larger radius portion (15e2). The gear (26) is secured 
to an end of a twisting shaft (27) passing through the spacer (11b). A 
square stopper (28) is secured adjacent to the gear (26). Since the 
stopper (28) is within the rotating locus zone of the larger radius 
portion (15e2), the stopper (28) prevents the twisting shaft (27) from 
rotating when the stopper (28) is covered by the larger radius portion 
(15e2) as one side of the stopper (28) is in contact with the back surface 
of the larger radius portion (15e2). However, when the smaller radius 
portion (15e3) comes to face the stopper (28), the twisting shaft (27) is 
permitted to rotate as the gear (26) engages with the teeth row (15e4). 
The twisting shaft (27) extends through the spacer (11b) up to L position 
before the recesses (10a4, 10b4). As shown in FIG. 17, a generally 
S-shaped twisting head (29) is secured to the end of the twisting shaft 
(27). An electric motor is disposed to the left of the base plate (10a) so 
as to drive the drive shaft (15) by way of a gear (not shown). The 
electric motor drives the drive shaft (15) by one turn every time the 
switch (not shown) is operated. 
The operation of the embodiment constituted as described above will be 
described below. 
First when a finger is placed on the projection (16b) of the release lever 
(16) to press it down in the clockwise direction, the release lever (16) 
rotates, and the feed roller (13a) with its rotary shaft (13a1) supported 
by the projection (16c) moves away from the feed roller (13b). At the same 
time, the projection (16a) comes from under into contact with the manual 
drive lever (14d1) of the release arm (14) to rotate the release arm (14) 
counterclockwise. This causes the feed roller (12a) with its shaft (12a1) 
held by the end of the release arm (14) to move away from the feed roller 
(12b). As a result, the feed rollers (12a, 12b) move away from the feed 
rollers (13a, 13b) to produce an elongate space between the spacers (11a, 
11b) through which the binding string is inserted. When the binding string 
is moved to the front end of the spacer (11b), the operators finger is 
released from the release lever (16). This causes the upper side feed 
rollers (12a, 13a) to be pressed down against the lower side feed rollers 
(12b, 13b) by the contraction force of the springs (14e, 16b) so that the 
binding string is held between the feed rollers. 
When rod-like objects to be bound are inserted in the recesses (10a4, 10b4) 
and the drive shaft (15) is driven by the electric motor, the gear portion 
(15a1) of the partially cogged gear (15a) comes to engage with the gear 
(12b) secured to the shaft (12b1) of the feed roller (12) to rotate the 
feed roller (12) counterclockwise. The feed roller (12b) rotates while the 
gear portion (15a1) of the partially cogged gear (15a) is in engagement 
with the gear (12b) and the binding string is fed toward the recesses 
(10a4, 10b4). 
As the drive shaft (15) rotates and the binding string is fed out, the 
projection (15c1) of the manual drive cam (15c) comes into contact with 
the projection (17a1) of the swing cam (17) to rotate the swing cam (17) 
clockwise as seen in FIG. 9. Then the drive arm (18) connected to the 
swing cam (17) is also rotated clockwise by the link (18a), and the slide 
base plate (19) connected through the support pins (18c1, 18c2) is driven 
forward. The curved member (20) held on the slide base plate (20) begins 
to move forward in an arcuate path. 
The back plate (21) secured on the curved member (20) moves forward up to a 
position above the position where the binding string is fed out. As the 
slide base plate (19) moves forward, the rocker arm (22) also moves 
forward. Since the guide slide pin (22b) at the rear end of the rocker arm 
(22) moves along the drive guide slot (10b3) in the base plate (10b), the 
guide slide pin (22b) turns downward clockwise. Then the curved member 
(20) in engagement with the gear portion (22a) of the rocker arm (22) 
begins to rotate counterclockwise on the slide base plate (19), and 
further rotates quickly while the objects to be bound are taken into the 
hook-shaped recess. 
At first the binding string is fed out between the spacers (11a, 11b) in 
the direction obliquely upward over the vicinity of the objects to be 
bound. When the front end of the binding string reaches approximately the 
position beyond the objects to be bound, the curved member (20) begins to 
turn around the objects to be bound to press and turn the front end of the 
binding string from above downward, and further turn in a U shape around 
the objects to be bound so that the binding string girdles the objects to 
be bound. Here, since the twisting shaft (27) is arranged in an oblique 
attitude so that the bound objects are fed out obliquely upward, the 
cutter body (23a) can cut the binding string at a position close to the 
bound objects. 
When the binding string is fed out by a length enough to girdle the objects 
to be bound, the projection (15b1) of the feed amount regulating drive cam 
(15b) comes from under into contact with the projection (14a1) of the 
regulator plate (14a) secured to the release arm (14) so that the release 
arm (14) is raised and rotated counterclockwise. Then the feed roller 
(12a) which has been pressing the binding string from above against the 
feed roller (12b) is moved upward, and the feed roller begins idle 
turning. Here, even if a force is exerted to pull the binding string in 
the reverse direction, the binding string cannot be drawn out in the 
reverse direction as long as the feed roller (13a) is pressing the binding 
string against the feed roller (13b) because the feed roller (13b) with a 
built-in one-way clutch cannot rotate in the reverse direction. When the 
gear portion (15a1) of the partially cogged gear (15a) runs out, the 
projection (15b1) moves away from the projection (14a1) of the regulator 
plate (14a) so that the release arm (14) is returned to the original 
position and the binding string is not fed out any more because the feed 
roller (12b) does not rotate. 
When the feeding of the binding string is stopped and the fore-end of the 
curved member (20) presses the end of the binding string against the 
objects to be bound, the projection (15e1) formed on the rotary cam (15e) 
begins to contact the end of the cutter drive arm (23d) to rotate the 
cutter drive arm (23d) counterclockwise about its axis. Then the cutter 
body (23a) also rotates counterclockwise, and the cutter blade (23b) held 
at the end of the cutter body slides downward while being pressed by the 
spring (23c) against the counter blade (24). As a result, the binding 
string being fed out through the U-shaped opening of the counter blade 
(24) is cut by a guillotine action. 
Along with the rotation of the cutter body (23a), the holding plate (25) 
rotates, and its downwardly bent end presses the tail end portion of the 
binding string against the twisting head (29), and the curved member (20) 
presses the front end of the binding string against the twisting head 
(29). Then the stopper (28) of the twisting shaft (27) is released from 
the larger radius portion (15e2) of the rotary cam (15e), faces the 
smaller radius portion (15e3), engages with the gear teeth row (15a4) of 
the cam (15e) to start the rotation of the twisting shaft (27). Then, as 
shown in FIG. 17, the S-shaped twisting head (29) takes both ends of the 
binding string into its two openings, twists those ends and bind them 
together. 
About the time the twisting head (29) begins to twist both ends of the 
binding string, the projection (15c1) of the manual drive cam (15c) begins 
to come into contact with the projection (17a2) of the swing cam (17) to 
rotate the swing cam (17) in the direction opposite to that described 
above. As a result, the drive arm (18) also rotates in the opposite 
direction to reverse the slide base plate (19) supported by the support 
pins (18c1, 18c2), and the curved member (20) moves in the direction 
opposite to that described above to move apart from the objects to be 
bound. In a similar manner, the projection (15e1) of the cam (15e) moves 
away from the cutter drive arm (23d), and the cutter body (23a) returns to 
the original position. 
When the twisting head (29) twists the ends of the binding string by a 
specified number of turns, the larger radius portion (15e2) of the cam 
(15e) approaches, and the gear (26) disengages from the gear teeth row 
(15e4). The stopper (28) comes into sliding contact with the back surface 
of the larger radius portion (15e2), and the rotation of the twisting 
shaft (27) stops. When the drive shaft (15) has made one turn, the binding 
is complete and the electric motor stops its rotation. 
FIG. 18 shows the binding machine in a horizontal attitude showing an 
example of application to a bag for confectionery or the like by inserting 
the upper portion of the bag into the recesses (10a4, 10b4) for binding. 
As shown in the figure, protection covers (30a, 30b) for safety are 
attached to both sides of the base plate (10b). The binding string is 
wound on a reel (32) supported by a support plate (31). 
FIG. 19 shows an example of application of the binder of this invention to 
binding the flowerpot poles. FIG. 20 shows the application to binding the 
looped metallic wire. FIG. 21 shows the state of binding crossed iron by 
inserting the crossed portion into the recesses (10a4, 10b4). As shown in 
the figures, in this embodiment, the electric motor is arranged to the 
right of the base plate (10b) and a handle (33) is provided for easy 
portability. The handle (33) is provided with a switch (34) which is 
constituted to perform one binding with one push on the switch (34). 
As described above, the slide base plate (19) is moved back and forth in an 
arcuate path while the drive arm (18) swings about its axis. Along with 
the back and forth movement of the hook-shaped curved member (20) held on 
the slide base plate (19), the guide slide pin (22b) of the rocker arm 
(22) moves within the drive guide slot (10b3) in the base plate (10b) to 
rotate the rocker arm (22) so that the curved member (20) connected to it 
is turned quickly. As described above, since the curved member (20) makes 
the arcuate back and forth movement while it is pressed against the 
binding string, the binding is performed with a simple mechanism.