Two contraction-expansion pieces each have one end thereof connected to a base plate secured to a main body containing therein an opening and the other end thereof connected to a base plate secured to a lid serving to open and close the opening of the main body. The two contraction-expansion pieces which are each provided with a constricted, flexible elbow portion are pivotally fastened independently of each other and arranged in a mutually crossing state. Consequently, the two contraction-expansion pieces and the two base plates jointly form a pantographic mechanism. When the lid which is locked to the main body to keep the opening in its closed state while holding the pantographic mechanism in its folded state is released from the main body, the pantographic mechanism automatically expands and the lid is consequently brought to a completely opened state.

BACKGROUND OF THE INVENTION 
This invention relates to an open-close device for disposal between a main 
body containing therein an opening and an open-close member capable of 
closing the aforementioned opening, for attaching the open-close member to 
the main body so as to be operable to open and close the opening. 
As one typical example of prior art, there may be cited Japanese Utility 
Model Examined Publication No. 49(1974)/47567 which discloses a metallic 
open-close device formed of two pairs of movable members pantographically 
assembled by having one of the pairs of movable members pivotally fastened 
with pins at spaced locations to a first base plate secured to an inner 
surface of a main body, the other pair of movable members pivotally 
fastened with pins at spaced locations to a second base plate secured to a 
lid serving as an open-close member, the free ends of the movable members 
of one pair pivotally fastened with pins to the free ends of the 
corresponding movable members of the other pair, and the mutually crossing 
movable members, one from each of the two pairs, pivotally fastened to 
each other with a pin at the point of intersection thereof. 
This metallic open-close device of the prior art is formed of two base 
plates and four movable members and assembled by use of seven pins. Since 
the number of component parts is very large, the work of assembling this 
device entails much time and labor. Further within this pantographic 
mechanism, there is separately incorporated a spring plunger unit which 
assumes the most compressed state at the medial length of its expansion or 
contraction and manifests its resiliency during its expansion or 
contraction past the aforementioned medial length. Thus, the spring 
plunger unit enables the device to produce a quickened motion during its 
operation. 
An arrangement wherein the lid is normally locked in its closed state by 
means of a lock provided at the free end of the lid and, when necessary, 
the lid is automatically opened completely or partially by releasing the 
lock can not be accomplished with the aforementioned spring plunger unit. 
In any event, in the conventional pantographic open-close device, a 
movement making use of resiliency cannot be produced unless the device 
separately incorporates therein spring means. This inconvenience is 
similarly experienced by the open-close device disclosed in Japanese 
Utility Model Unexamined Publication No. 52(1977)/77376. 
An object of this invention is to provide an open-close device which 
comprises only few parts molded of a plastic substance and, therefore, is 
capable of easy assemblage. 
Another object of this invention is to provide a pantographic open-close 
device which is adapted so that an open-close member (the lid) is brought 
into its locked position to close the opening in the main body by 
contraction of the pantographic mechanism and the open-close member is 
brought into its completely or partially opened state by releasing the 
lock and consequently allowing the pantographic mechanism to expand 
automatically. 
SUMMARY OF THE INVENTION 
To accomplish the objects described above according to the present 
invention, there is provided a plastic pantographic open-close device 
which comprises first and second contraction-expansion pieces each formed 
of a pair of arms connected to each other through the medium of an elbow 
portion, two base plates one of which is secured to a main body containing 
an opening and the other of which is secured to an open-close member 
adapted to open and close the opening of the main body, one end of each 
contraction-expansion piece being connected to one of the base plates and 
the other end thereof being connected to the other base plate, the 
connection being an integral connection through an elbow portion either at 
both ends of one contraction-expansion piece and one end of the other 
contraction-expansion piece or at one end of each contraction-expansion 
piece and being through pivoted portions at the remaining ends of the 
contraction-expansion pieces, one of the arms of the first 
contraction-expansion piece and one of the arms of the second 
contraction-expansion piece being pivotally fastened and arranged in a 
crossing state, the first and second contraction-expansion pieces and the 
base plates jointly forming a pantographic mechanism, whereby the elbow 
portions accumulate therein, from the resiliency of the plastic material 
of which the device is made, a force to expand the pantographic mechanism 
large enough to overcome the total of frictional force generated by the 
pivoted portions when the pantographic mechanism is folded down to have 
the open-close member close the opening of the main body and the force 
thus accumulated serves the purpose of constantly keeping the pantographic 
mechanism energized in the direction of its expansion. 
The open-close device of the present invention can be integrally molded of 
a plastic material. Thus, the device enjoys the advantage that it can be 
inexpensively produced and assembled in a short time with little labor. 
When the open-close member (lid) which is locked to the main body to keep 
the opening in its closed state while keeping the pantographic mechanism 
in its folded state is released from the main body, the pantographic 
mechanism is automatically expanded and the open-close member is 
consequently brought to a completely or partially opened state.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
FIG. 1(A), FIG. 1(B) illustrates the metallic open-close device disclosed 
in Japanese Utility Model Examined Publication No. 49(1974)/47567. In the 
drawing, a pair of movable members 3a, 4a are pivotally fastened with pins 
3, 4 at spaced locations to a first base plate 2 secured onto the inner 
surface of a main body 1, a pair of movable members 3b, 4b are pivotally 
fastened with pins 3', 4' at spaced locations to a second base plate 6 
secured to a lid 5 serving as an open-close member, the free ends of 
movable members 3a, 3b are pivotally fastened to the corresponding free 
ends of movable members 4a, 4b with pins 7, 8 and the movable members 3b, 
4a which cross each other are pivotally fastened with a pin 9 to each 
other at their intersection to form a pantographically assembled 
open-close device. This metallic open-close device of the prior art is 
formed of two base plates 2, 6 and four movable members 3a, 3b, 4a and 4b 
and assembled by use of seven pins 3, 3', 4, 4', 7, 8 and 9. Since the 
number of component parts is large, the work of assembling this device 
entails much time and labor. Further within this pantographic mechanism, 
there is separately incorporated a spring plunger unit which assumes the 
most compressed state at the medial length of its expansion or contraction 
and manifests its resiliency during its expansion or contraction past the 
aforementioned medial length. Thus, the spring plunger unit enables the 
device to produce a quickened motion during its operation. An arrangement 
wherein the lid is normally locked in its closed state by means of a lock 
provided at the free end of the lid and, when necessary, the lid is 
automatically opened completely or partially by releasing the lock can not 
be accomplished with the aforementioned spring plunger unit. 
Now, the first embodiment of the open-close device of the present invention 
will be described with reference to FIGS. 2 to 7. 
Referring to FIGS. 2 to 7, the open-close device 10 of the present 
invention possesses separately formed first and second 
contraction-expansion pieces 14, 18. The first contraction-expansion piece 
14 is provided at one end thereof with a stationary base plate 19 secured 
immovably to the inner surface of the main body 1 and at the other end 
thereof with a movable base plate 20 secured to the inner surface of the 
open-close member 5 and, therefore, allowed to move simultaneously with 
the open-close member. The constricted portions of the two 
contraction-expansion pieces are molded of a suitable plastic substance 
such as a polypropylene resin which manifests proper resilience. 
To be more specific, the open-close device of this invention possesses the 
first contraction-expansion piece 14 provided with a pair of arms 12, 13 
connected to each other through an elbow portion 11 and the second 
contraction-expansion piece 18 provided with a pair of arms 16, 17 
similarly connected to each other through an elbow portion 15. The 
stationary base plate 19 and the movable base plate 20 are connected to 
the opposite ends of the first contraction-expansion piece 14 respectively 
with elbow portions 19', 20'. The elbow portions 11, 15, 19' and 20' are 
all constructed in a constricted manner and, therefore, are flexible. 
The arms 12, 13 of the first contraction-expansion piece 14 correspond to 
the movable members 3a, 3b of the conventional open-close device of FIG. 1 
and the arms 16, 17 of the second contraction-expansion piece 18 similarly 
correspond to the movable members 4a, 4b. The elbow portions 11, 15 
correspond to the pins 7, 8 and the elbow portions 19', 20' similarly 
correspond to the pins 3, 3'. As a result, the four pins 3, 3', 7 and 8 
used in the conventional device are eliminated in the device of the 
present invention. Where the conventional device necessitates use of six 
component parts, namely two base plates 2, 6 and four movable members 3a, 
3b, 4a and 4b, only two plastic molded pieces, namely the first and second 
contraction-expansion pieces, will do in the present embodiment. 
The arms 12, 13 of the first contraction-expansion piece 14 are 
plate-shaped. For the arm 13 and the arm 17 of the second 
contraction-expansion piece to be pivotally fastened to each other in a 
mutually intersecting state, the arm 13 is provided midway of the length 
thereof with a lateral hole 21 for passing a pin (FIGS. 4 and 5). The arm 
17 of the second contraction-expansion piece 18 comprises a plate piece 
17a continuing at one end thereof into the elbow portion 15 and beams 17b 
contiguous with the opposite lateral edges of the plate piece 17a. The 
beams 17b are spaced at an interval W' greater than the width W of the arm 
13 and protrude considerably past the other end of the plate piece 17a 
(FIGS. 6 and 7). The beams 17b have holes 22 at positions close to the end 
of the plate piece 17a furthest from the elbow portion 15. The pivotal 
fastening of the arms 13, 17, therefore, is accomplished by having the arm 
13 inserted in a crossing state in the internal W' of the opposite beams 
17b, causing the holes 21, 22 to coincide with one another and passing a 
pin 23 through the coinciding holes. 
The stationary base plate 19 and the movable base plate 20 have insertion 
holes 24, 25 formed parallelly to the hole 21 at locations separated from 
the elbow portions 19', 20'. In order that the leading end of the arm 17 
of the second contraction-expansion piece 18 may be pivotally fastened to 
the stationary base plate 19 through the medium of pin 28 and insertion 
hole 24, the beams 17b are provided at their leading ends with holes 26. 
The other arm 16 of the second contraction-expansion piece, similarly to 
the arm 17, is provided with a plate piece 16a continuing at one end 
thereof into the elbow portion 15 and beams 16b contiguous with the 
opposite lateral edges of the plate piece 16a and slightly protruding from 
the other end of the plate piece 16a. The beams 16b are provided at their 
leading ends with holes 27. Through the medium of pin 29 and insertion 
hole 25, these beams are pivotally fastened with the movable base plate 
20. 
Consequently, the extremities of the arms 16, 17 of the second 
contraction-expansion piece 18 can be pivotally fastened to the base 
plates 19, 20 respectively by bending the two contraction-expansion pieces 
at the elbow portions 11, 15, folding the two base plates 19, 20 at the 
elbow portions 19', 20' relative to the arms 12, 13, passing a pin 28 
through the holes 26 at the leading ends of the arm 17 and the insertion 
hole 24 of the stationary base plate 19 and further passing a pin 29 
through the holes 27 at the leading end of the arm 16 and the insertion 
hole 25 of the movable base plate 20. Thus, the two contraction-expansion 
pieces 14, 18 are assembled by use of three pins 23, 28 and 29 into a 
pantographic open-close device 10. 
In the present embodiment, the insertion holes 21, 24 and 25 provided in 
the plate-shaped arm 13 have a common construction which comprises a 
central groove 30a having a cross section conforming to one half of the 
circle of a pin and two distal grooves 30b having a cross section 
conforming to the other half of the circle of the pin and disposed to 
adjoin the central groove 30a at the opposite ends thereof, with the 
central groove 30a formed in one surface of the plate and the distal 
grooves 30b formed in the other surface of the plate. This specific 
formation of grooves is purely for convenience in molding. The grooves, 
therefore, need not be limited to this specific pattern. The pins 23, 28 
and 29 used for the insertion holes 21, 24 and 25 may be metallic cotter 
pins or other similar pins. For example, as shown in FIG. 8, pins each 
comprising a shank 31, a head portion 31a formed at one end of the shank 
and a conically expanded portion 31c formed at the other end of the shank 
and adapted to be radially contracted by virtue of a slit 31b may be 
obtained by injection molding a plastic substance. These plastic pins are 
passed through the insertion holes and the holes, i.e. 21 and 22, 24 and 
26, and 25 and 27, with the conically expanded portions 31c contracted 
radially and the conically expanded portions 31c upon emergence from the 
holes, and are allowed to resume their original state and consequently 
remain irremovably in the holes. Either the insertion holes 21, 24 and 25 
or the holes 22, 26 and 27 may be replaced with integrally molded 
pin-shaped projections 23', 28' and 29' as shown in FIG. 5 and FIG. 7 and 
these projections may be inserted into the corresponding insertion holes 
or holes to effect the pivotal fastening. This arrangement offers the 
advantage of even obviating the necessity for using three pins for the 
pivotal fastening. 
In the open-close device 10 of the construction described above, the 
stationary base plate 19 is secured to the inner surface of the wall of 
the main body 1 which bends down from the edge of the opening and the 
movable base plate 20 is secured to the inner surface of the hinged side 
of the open-close member 5 such as a lid capable of closing the 
aforementioned opening (FIG. 2). When the lid is in its opened state, the 
pantographic mechanism of the device is expanded, the base plates 19, 20 
run substantially parallelly to each other and the elbow portions 11, 15 
are stretched out (FIG. 3(B)). When the lid is closed with the free end of 
the open-close member locked to the main body 1, the elbow portions 11, 15 
are bent largely and the two contraction-expansion pieces 14, 18 are 
respectively folded back. Consequently, the pantographic mechanism is 
collapsed to bring the movable base plate 20 to a position substantially 
perpendicular to the stationary base plate 19, and the elbow portions, 
particularly 11, 15, acquire force tending to elongate the pantographic 
mechanism (FIG. 3(A)). When the free end of the open-close member is 
unlocked from the main body, the force built up in the elbow portions 
causes the contraction-expansion pieces 14, 18 to stretch out to expand 
the pantographic mechanism and automatically cause the open-close member 
to open completely or partially. 
In any event, when the pantographic mechanism is folded down to bring the 
open-close member into its locked position, the elbow portions, owing to 
the resilient property of the plastic substance of which the elbow 
portions are made, store energy therein capable of expanding the 
pantographic mechanism by overcoming the total sum of the frictional 
forces of the pins 23, 28 and 29 or the pin-shaped projections 23', 28' 
and 29' at the pivotally fastened portions. The resiliently stored energy 
energizes the pantographic mechanism in the direction of its expansion. In 
the present embodiment, the accumulation of this energy occurs 
preponderantly in the elbow portions 11, 15. The elbow portions 11, 15 are 
so constructed that the sum of the energy accumulated therein will be 
greater than the total of frictional forces at the pivotally fastened 
portions. In this respect, the elbow portion 20' plays an auxiliary part. 
As occasion demands, the elbow portions may be constructed so that the 
total of energy accumulated in three elbow portions 11, 15 and 20' is 
barely enough to overcome the total frictional force of the pivotally 
fastened portions or the energy accumulated in any one of the three elbow 
portions exceeds the total frictional force of the pivotally fastened 
portions. If the extent to which the pantographic mechanism is expanded by 
the resiliently stored energy in the elbow portions is not sufficient for 
the purpose of separating the open-close member from the opening, a spring 
(not shown) adapted to be contracted under the force generated by the 
folding of the pantographic mechanism may be provided between the arms 12, 
13 of the first contraction-expansion piece 14, so that the spring will 
exert the force required for opening the open-close member. 
The embodiment so far described has a construction wherein the stationary 
base plate 19 and the movable base plate 20 are connected to the opposite 
ends of the first contraction-expansion piece 14. For this reason, the 
stationary base plate 19 is folded backward at the elbow portion 19' 
relative to the arm so that the insertion hole 24 is positioned below the 
arm 12 and, through the medium of this insertion hole 24, the stationary 
base plate 19 may be pivotally fastened with the corresponding end of the 
arm 17 of the second contraction-expansion piece, giving rise to the 
pantographic mechanism. 
Alternatively, the stationary base plate 19, for example, may be connected 
through the medium of the elbow portion 19' to the end of the arm 17 of 
the second contraction-expansion piece so that the first 
contraction-expansion piece 14 will be provided with the movable base 
plate 20 and the second contraction-expansion piece 18 with the stationary 
base plate 19. The embodiment of FIG. 9 illustrates this modification. In 
this case, the stationary base plate 19 is connected through the medium of 
the elbow portion 19' to the end of the arm 17 in such a manner that it 
will extend forward from the aforementioned end. This base plate 19 is 
provided at the leading portion thereof with an insertion hole 25. In the 
first contraction-expansion piece, the arm 12 is provided at the opposite 
lateral sides with projections 12' protruding from the end portion of the 
arm, so that the desired pivotal fastening may be accomplished by means of 
the projections 12' and the insertion hole 25 and pin 28 mentioned above. 
Since the rest of the construction is similar to the construction of the 
preceding embodiment, like parts are designated by like symbols and the 
description thereof is omitted to avoid repetition. 
The two embodiments described above share a common principle that the first 
contraction-expansion piece 14 and the second contraction-expansion piece 
18 are separately molded of a plastic substance and they are assembled by 
pivotally fastening their relevant parts at three points. The present 
invention, however, can be accomplished otherwise by having the two 
contraction-expansion pieces integrally molded as illustrated in FIGS. 10 
and 11. Specifically in this case, the first contraction-expansion piece 
35 which comprises a pair of arms 33, 34 connected to each other through 
the medium of an elbow portion 32 has a base plate 37 connected to the arm 
33 through a flexible elbow portion 36, so that the first 
contraction-expansion piece 35 may be bent at the elbow portion 32 so as 
to assume the shape of a hill and, at the same time, the base plate 37 is 
bent at the elbow portion 36 relative to the arm 33. The other base plate 
38 is connected through an elbow portion 39 to the end of the other arm 
34. To the leading end of the base plate 38, one of the pair of arms 42, 
43 of the second contraction-expansion piece 41 which are connected to 
each other through the medium of an elbow portion 40 is connected through 
an elbow portion 44. In this case, the other arm 43 which is not connected 
to the base plate 38 is formed of a plate piece 43a having one end thereof 
constituting the elbow portion 40 and beams 43b, 43b rising from the 
opposite lateral edges of the plate piece 43a with an interval greater 
than the width of the arm 34 and protruding far past the other end of the 
plate piece 43a. Consequently, the arm 42 is bent at the elbow portion 44 
relative to the base plate 38 and, at the same time, the second 
contraction-expansion piece 41 which comprises the arms 42, 43 is bent in 
the shape of a hill at the elbow portion 40, the arm 34 of the first 
contraction-expansion piece is inserted in an intersecting manner in the 
space between the beams 43b and the arm 34 is pivotally fastened with the 
arm 43 and the end of the arm 43 similarly fastened with the base plate 37 
respectively (FIG. 11). In the present embodiment, therefore, the 
pantographic open-close device is assembled simply by effecting the 
pivotal fastening at two points in one molded plastic piece integrally 
containing two contraction-expansion pieces 35, 41 and two base plates 37, 
38. Thus, the assemblage of device is accomplished more simply in the 
present embodiment than in the aforementioned two embodiments. Of course, 
also in the present embodiment, the open-close device 10 is adapted so 
that the total force tending to cause expansion of the pantographic 
mechanism which the elbow portions 32, 39 and 40 accumulate therein while 
the pantographic mechanism is kept in its folded state is greater than the 
total of the frictional force generated at the two pivotally fastened 
portions and the resilient force generated at the elbow portions 36, 44. 
Consequently, the open-close device is energized in the direction of its 
expansion. 
The pivotal fastening can be obtained by use of pins. In the present 
embodiment, two pairs of pin-shaped projections 45, 46 integrally formed 
on the opposite lateral sides respectively of the arm 34 and the tail 
portion 37' which protrudes backwardly from the end of the base plate 37 
and matching holes 45', 46' are formed roughly in the middle and at the 
end respectively of the arm 43, so that the projections 45, 46 will be 
inserted respectively into the holes 45', 46'. Thus, the one molded 
plastic piece can be assembled into the pantographic open-close device all 
by itself. 
Any of the embodiments described so far may be additionally provided with 
engaging means 47 capable of retaining the open-close member 5 (the lid) 
of the device in its opened state after the pantographic mechanism has 
been expanded to separate the open-close member from the opening in the 
main body 1. This engaging means 47 locks the open-close device in its 
opened state and prevents it from unexpectedly closing the opening. This 
engaging means is illustrated as comprising a protuberating ridge 47b 
possessed of a head 47a and a groove 47c capable of resiliently admitting 
the head 47a, the ridge 47b and the groove 47c on the opposed surfaces of 
the parts adapted to approach each other when the pantographic mechanism 
is being expanded, namely the arm 12 and the base 19 in the case of the 
embodiments of FIGS. 2 to 7 and FIG. 9 or the arm 33 and the base plate 37 
in the case of the embodiment of FIGS. 10 and 11. This engaging means 47 
is so adapted that when the open-close member in its opened state is 
closed by exertion of slight force, the head 47a of the protuberating 
ridge 47b forces its way out of the groove 47c. Of course, the engaging 
means is not limited to this particular arrangement. Further, owing to the 
fact that the base plates 19, 20 or 37, 38 are molded of a plastic 
substance, they can be integrally provided with studs 48 useful for the 
purpose of attachment of the open-close device to the main body and the 
open-close member (FIG. 12). 
These studs 48 may be formed each in the well-known shape of an anchor 
which is passed in its contracted state through the matching hole bored in 
the main body or the open-close member and, after passage of the hole, 
allowed to resume its original shape owing to the resiliency and 
consequently remain fast in position behind the rear edge of the hole or 
in the known shape of a screw socket which is passed through the matching 
hole and, after passage of the hole, is expanded radially by insertion 
therein of a screw. Where the main body and the open-close member are 
allowed to be made of the same plastic substance as the base plates, such 
base plates can be molded as the main body and the open-close member. When 
the movable base plate 20 or 38 is molded as an open-close member, for 
example, the work of securing the base plate 20 or 38 to a separately 
molded open-close member. Since the open-close member which would 
otherwise be made of a metallic material is formed of a plastic substance 
in this case, it enjoys reduction of weight and protection against 
rusting. 
Further as illustrated in FIG. 13, a plurality of contraction-expansion 
pieces 14 (35), 18 (41) can be serially disposed for each pair of base 
plates 19, 20 or 37, 38. 
In the embodiment of FIGS. 2 to 7, the beams 17b of the arm 17 pivotally 
fastened in a state to cross the arm 13 continues to embrace within the 
space W' thereof the arm 12 connected to the arm 13 even after the 
pantographic mechanism has been expanded. In the embodiments of FIG. 9 and 
FIGS. 10 and 11, when the beams 17b, 43b of the arms are adapted so that 
they continue to embrace in the space W' thereof the arms 12, 33 not only 
when the pantographic mechanism is folded as shown by the dotted line but 
also when it is expanded, the open-close devices acquire enough strength 
to resist possible twisting. 
In all the embodiments given above, the elbow portions have been described 
as possessing a constricted flexible structure. Alternatively, some of the 
elbow portions may be formed in the shape of male-female hinges which 
offer higher rigidity and the remaining elbow portions may be adapted to 
energize the pantographic mechanism in the direction of expansion. 
The open-close device 10 of the present invention, for example, may be 
disposed between a lid 49 serving to close a recess in an automobile body 
where there is disposed a gasoline inlet and the portion of automobile 
body adjoining the recess (FIG. 14). Normally, the lid 49 is retained in 
its closed state by the lock 50. As soon as the lock is released, the lid 
49 automatically opens completely or partially. Thus, this arrangement 
offers great ease of operation and fulfills its purpose advantageously.