Clamping device

A clamping device of this invention is constructed of bases on which molds are slidably moved, regulating portions each provided above the corresponding base and having a clamping surface which is inclined relative to the base, shifting means provided beside the bases and for shifting each mold placed on the base in a direction to which the space between the base and the clamping surface progressively narrows and a spacer fixedly mounted on the upper surface of the mold, the upper surface of which being in the form of an arc in a direction to which the mold is moved. In use, each of the molds placed on the base is moved by the shifting means. The mold is then sandwiched between the base and the clamping surface and clamped to a wedge configuration.

BACKGROUND OF HE INVENTION 
1. Field of the Invention 
This invention relates to a clamping device which clamps molds used for 
transfer or injection molding of rubber or resin. 
2. Description of the Prior Art 
Heretofore, in a clamping device used for this kind of molding, for 
example, a mold 1 including an upper molding piece 1a and a lower molding 
piece 1b is sandwiched between pressure plates 3, 4 and is, then, clamped 
by means of a clamping cylinder 2 as shown in FIG. 1. It should be 
mentioned, however, that clamping force of the clamping cylinder 2 always 
needs be maintained during molding. Furthermore, it is difficult for only 
one clamping cylinder 2 to clamp a plurality of molds 1 at the same time. 
Thus, there are disadvantages that such clamping device is of larger size 
and is costly. 
SUMMARY OF THE INVENTION 
It is an object of this invention to provide a clamping device which 
requires less clamping force than a conventional clamping device. 
It is another object of this invention to provide a clamping device which 
enables maintaining clamping force after the completion of clamping 
process without using other power means and which enables clamping a 
plurality of molds by the use of one clamping cylinder or the like, 
thereby reducing the size and cost thereof. 
In order to achieve the above-mentioned objects, a clamping device 
according to this invention is constructed of a base on which a mold is 
slidably moved, regulating portions, provided above the base and having a 
clamping surface which is inclined relative to the base, shifting means 
provided beside the base and for shifting the mold placed on the base in a 
direction to which the space between the base and the clamping surface 
progressively narrows and a spacer fixedly mounted on the upper surface of 
the mold, the upper surface of which being in the form of an arc in a 
direction to which the mold is moved. Each mold placed on the base is 
moved by the shifting means and is sandwiched between the base and the 
clamping surface and then, clamped to a wedge configuration.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
In a clamping device according to one embodiment of this invention, each 
mold 11 including an upper molding piece 11a and a lower molding piece 11b 
is clamped in a holder 13 in the form of a box having two horizontally 
extending holes 13a. Formed on the lower surface of each of the two insert 
holes or chambers 13a which open through opposite ends of the holder is a 
base 14 in the form of a plane on which the mold 11 is slidably moved. On 
the other hand, formed on the upper surface of each of the insert holes 
13a is a clamping surface 15a which is inclined relative to the 
corresponding base 14 in such a manner that the space between the base and 
the clamping surface is progressively narrower towards the respective rear 
portion thereof. Each of regulating portions 15 is connected via side 
walls 16 to the base 14. Further, formed near the central portion of the 
two insert holes 13a in its axial direction are apertures 15b, 15b through 
which an injection pot or a nozzle of an injection machine is inserted for 
the purpose of supplying material into the mold 11 when the mold 11 is 
clamped. 
The holder 13 is shifted from one process to another in a circulating 
manner by a feed means (not shown), such processes including clamping, 
material injecting, vulcanizing, mold opening and closing, mold removing 
and the like. In the mold clamping process, a clamping cylinder 12 is 
provided behind the insert hole 13a in the holder 13 as a means for 
pulling the mold 11 so that the mold 11 is slidably moved on the base 14. 
The mold 11 is provided at its rear end with a hook 18 for engagement with 
the clamping cylinder 12. Further, spacers 17, 17, the upper surface of 
each of which being in the form of an arc, are fixedly mounted on both 
side edges of the upper surface of the upper molding piece 11a along its 
axial direction. It is to be noted that in order to evenly clamp the whole 
surface of the mold 11, the spacers 17, 17 are positioned in such a manner 
that a portion where these spacers 17, 17 are in abutment with the 
below-mentioned clamping surface 15a is located at the middle of the mold 
11 in its axial direction. Centrally formed on the upper surface of the 
upper molding piece is a hole 11c serving as a sprue when material is 
supplied. Additionally, guide pins or the like are provided in the 
interior of each of the upper molding piece 11a and the lower molding 
piece 11b so that the mold 11 may be opened and closed in a vertical 
direction. 
Use of the clamping device of this embodiment will now be described. 
The mold 11 placed on the base 14 is pulled upon engagement of the hook 18 
with the clamping cylinder 12 and is thereby slidably moved thereon. Thus, 
the spacers 17, 17 on the upper surface of the mold 11 are brought into 
abutment with the clamping surface 15a of the regulating portion 15. 
When the mold 11 is further pulled by means of the clamping cylinder 12, it 
is sandwiched between the base 14 and the clamping surface 15b and then, 
clamped to a wedge configuration. 
Here, pulling force F of the clamping cylinder 12 is represented by the 
following formula (1): 
EQU F=N sin .alpha.+R cos .alpha. (1) 
where N is normal force, R is frictional force and .alpha. is the angle of 
which the clamping surface is inclined relative to the base 14. Also, 
clamping force W of the mold 11 can be expressed as: W=N cos .alpha.. 
Substitution of this into the formula (1) gives 
EQU F=W sin .alpha./cos .alpha.=R cos .alpha. 
Then, 
EQU W=(F-R cos .alpha.)/tan .alpha. (2) 
If coefficient of friction between the spacers 17 and the clamping surface 
15a is denoted by .mu., R is expressed as: R=.mu.N=.mu.W/cos .alpha.. 
Further, substitution of this into the formula (2) gives 
EQU W=(F-.mu.W)/tan .alpha. 
Then, 
EQU W=F/(tan .alpha.+.mu.) (3) 
Now, the angle .alpha. of inclination is 2.degree. and coefficient of 
friction .mu. ranges from 0.35 to 0.40 if the spacers 17, 17 and the 
regulating portion 15 are both made of hard steel. Substitution of these 
values into the formula (3) gives 
##EQU1## 
From the above, it can be said that the mold 11 may be clamped by a force 
which is two times greater than that which can be provided by the clamping 
cylinder 12. In addition, clamping force may be maintained by frictional 
force between the spacers 17, 17 and the clamping surface 15 even if the 
clamping cylinder 12 is disengaged from the hook 18. Thus, the clamping 
cylinder 12 need not be continuously operated, unlike the conventional 
process. 
The angle .alpha. of inclination in relation to frictional force with 
regard to the clamping surface 15a for maintaining clamping force while 
clamping will now be considered. Force F necessary to release the mold 11 
from the holder 13 is represented by the following formula: 
EQU -F=N sin .alpha.-R cos .alpha. 
This is due to the fact that pulling force F and frictional force R are in 
opposite relation to the case shown in the formula (1). Since R is 
expressed as .mu.N and further, as N tan .lambda. (.lambda. is the angle 
of friction between the spacers 17 and the clamping surface 15a), F is 
represented by the following formula: 
##EQU2## 
It is to be noted that .lambda. is greater than .alpha.. This is due to 
the fact that if F is below zero, the mold 11 is naturally subject to 
release. Accordingly, the angle .alpha. of inclination of the clamping 
surface 15a is established smaller than the angle .lambda. of friction 
between the spacers 17, 17 and the clamping surface 15a. Should both the 
spacers 17, 17 and regulating portion 15 be made of hard steel, the 
coefficient of friction .mu. ranges approximately from 0.35 to 0.40. When 
the value of .mu.(=0.35) is inserted in the equation: .mu.=tan .lambda., 
.lambda.is approximately 19.degree.. Thus, the angle .alpha. of 
inclination of the clamping surface 15a is established smaller than 
19.degree.. 
After the mold 11 is clamped in the holder 13, the holder 13 is moved by 
the feed means (not shown). Another mold in the other insert chamber 13a 
is clamped by means of the clamping cylinder 12 and the holder is again 
moved by the feed means. Subsequently thereafter molds to be placed in 
front of the clamping cylinder 12 are clamped and moved from the material 
injecting station to a mold removing station through a vulcanizing station 
and a mold opening and closing station. A this time, the mold 11 within 
the holder 13 is kept clamped even if the clamping cylinder 12 is released 
therefrom. Thus, a plurality of molds may be clamped by only one clamping 
cylinder 12. Further, when the mold 11 is clamped, the arc-like spacers 
17, 17 are in abutment with the inclined clamping surface 15a. Hence, 
clamping force may evenly be effected even if the surfaces of the spacers 
17, 17 and the clamping surface 15a are not sufficiently finished. 
In the embodiment as above, the clamping cylinder 12 is provided behind the 
holder 13 as a means for abuting the spacers 17, 17 on the upper surface 
of the mold 11 with the clamping surface 15a upon movement of the mold 11. 
Alternatively, such means as a pusher or the like may be provided in front 
of the holder 13 so as to push the mold 11 from the front side of the 
holder 13 unless the mold 11 is released from the upper surface of the 
base 14. 
Further, in the embodiment, the mold 11 is arranged transversely. 
Alternatively, the mold 11 and the holder 13 may be arranged vertically if 
guide rails or the like be provided in a manner to alternately engage the 
base 14 and the lower surface of the lower molding piece 11b. 
Still further, in the embodiment, the spacers 17, 17 are fixedly mounted on 
both side edges of the upper surface of the upper molding piece 11a. If 
the sprue 11c is provided on one side of the mold 11 rather than on the 
upper portion of the upper molding piece 11a, only one spacer 17 is 
necessary to be provided at the central portion of the upper surface of 
the upper molding piece 11a. In addition, the arc portion forced on the 
upper surface of each of the spacers 17, 17 is preferably of larger radius 
in view of abrasion.