Reinforcing steel shear

A reinforcing steel shear including a stationary lower jaw and a movable upper jaw, the upper jaw being divided into two segments which can be bolted together in alternative positions to change the maximum allowable degree of jaw opening. This adjustable jaw opening feature makes the shear useful for various shearing load sizes.

TECHNICAL FIELD 
The present invention relates to a heavy duty shear for use in the 
demolition of buildings and other applications. 
BACKGROUND OF THE INVENTION 
Generally, in the demolition of reinforced concrete buildings, a 
reinforcement shear mounted at the free end of the arm of a power shovel 
is employed. As an example of such shear, there is known a shear 
comprising a stationary lower jaw having a cutting edge and a movable 
upper jaw having an associated cutting edge and adapted to open and close 
with respect to said stationary lower jaw, said cutting edges being 
respectively straight edges (cf. Japanese Utility Model Application Kokai 
S-54-167871). 
This type of shear having straight cutting edges as mentioned above can 
shear iron sheet and the like neatly but cannot shear reinforcing steel or 
the like because such a shearing load tends to slip forward unless fixed 
somehow in position. 
To solve this problem, U.S. Pat. No. 4,519,135 proposes a shear illustrated 
in FIG. 6. This shear comprises a lower jaw I rigidly mounted on the arm 2 
of a power shovel and an upper jaw 4 connected to said lower jaw 1 through 
a pivot 4 so that the upper jaw may open and close with respect to the 
lower jaw. In use of the shear, the steel reinforcement, for instance, is 
trapped between said upper and lower jaws and the upper jaw 4 is then 
closed by means of an associated hydraulic cylinder 5 to shear the 
reinforcement. In this shear, the upper and lower jaws are recessed away 
from each other in a longitudinally intermediate position to prevent 
forward displacement of the gripped load on shearing. 
In addition, the upper jaw 4 is formed as a single member and the lower jaw 
1 as two parallel members so that the forward end of the upper jaw 4 may 
descend into the clearance between the two members of the lower jaw 1. 
These two parallel members of the lower jaw 1 are interconnected by a 
front end member 6. The mating edge portions of the upper and lower jaws 
1,4 are respectively provided with plural cutting edges 7,8,9,10. 
Moreover, wear plates 11,12 are rigidly secured to the upper and lower 
jaws, respectively, on the side opposite to said cutting edges 7,8,9,10 so 
that the upper jaw 4 will not be deflected sideways in shearing. 
However, the proposed shear has the problem that the cutting edge 7 of the 
upper jaw 4 and that 9 of the lower jaw 1 are parallel even in the maximum 
opening position of the jaws and do not open further so that the maximum 
degree of opening cannot be large. In other words, generally any shear 
designed to preclude a forward slip of the gripped load cannot have a 
large opening. 
SUMMARY OF THE INVENTION 
The object of the present invention is to overcome the above disadvantages 
of the prior art. 
The present invention is directed to a reinforcement steel shear adapted to 
be swingably mounted at the forward end of a construction machine arm and 
including a stationary lower jaw having cutting edge means and a movable 
upper jaw having cutting edge means for shearing a load, comprising a 
hydraulic cylinder disposed in a substantially vertical position and 
connected to said upper jaw at its rear end, said upper jaw being divided 
into a forward segment and a rear segment which are interconnected by bolt 
means selectively installed in one or another set of bolt holes provided 
in a plurality of rows whose imaginary downward extensions intersect each 
other. 
The present invention is now described in further detail with reference to 
the accompanying drawings which illustrate the preferred embodiments.

DETAILED DESCRIPTION OF THE INVENTION 
The steel shear of the invention weighs about 3800 kg and has a cutting 
edge length of about 800 mm. This steel sheer, shown in FIGS. 1 through 4, 
is characterized in that the maximum opening of its jaws can be 
selectively set to two degrees, viz. about 600 mm and about 390 mm. 
This steel shear has a lower jaw 1 extending integrally from a shear body 
13 and an upper jaw 4 which is swingably connected to said lower jaw 
through a pivotal shaft 3 in such a manner that the upper jaw 4 may swing 
vertically to open and close with respect to said lower jaw 1. When a 
shearing load is trapped between the upper jaw 4 and lower jaw 1 in the 
above arrangement and the upper jaw 1 is closed by means of an associated 
hydraulic cylinder 5a, the load trapped between the jaws is firmly gripped 
and shorn. 
The upper jaw 4 and lower jaw 1 are recessed apart in an intermediate 
longitudinal position so that the gripped load will not slide 
longitudinally forward on gripping and shearing. 
The upper surface of the lower jaw 1 is formed with a land 1a configured in 
the shape of the numeral "7" and two cutting edges 9 and 10 are mounted on 
the shank portion of this 7-shaped land as shown in FIGS. 1 and 2. 
Furthermore, the forward end of the lower jaw 1 is provided with a 
through-opening 14 for accepting the overlying forward end of the upper 
jaw 4. 
The bottom of said shear body 13 is provided with cylinder bosses 15 by 
which the free end of a piston rod 16 of a hydraulic cylinder 5a is 
rotatably supported. This hydraulic cylinder 5a is disposed in a 
substantially vertical position within the shear body 13 and connected to 
the rear end of said upper jaw 4. Thus, as the hydraulic cylinder 5a is 
operated, the upper jaw 4 is caused to swing upward or downward to open or 
close with respect to the lower jaw 1. 
A bracket 18 is rigidly secured to the rear wall of the shear body 13 
through a swing bearing 17. This bracket 18 is provided with an arm pin 19 
for coupling with the arm of a power shovel (not shown) and a pin 20 to 
which the force of a booming hydraulic cylinder (which is installed in 
parallel with said arm) is transmitted for rotating the bracket 18. 
The swing bearing 17 mentioned above has a built-in internal gear (not 
shown) which is in mesh with the pinion of a built-in hydraulic motor (not 
shown), whereby the steel shear may be swung through 360.degree. with 
respect to the power shovel arm. 
In this embodiment of the invention, the maximum opening between cutting 
edges 7 and 9 may be selectively set to whichever of two degrees. Thus, 
the upper jaw 4 is divided into a forward upper jaw segment 21 and a rear 
upper jaw segment 22 and a cutting edge is mounted on each of said 
for-ward and rear upper jaw segments 21,22. Stated differently, the upper 
jaw 4 is split into two parts along the junction between the cutting edges 
7 and 8. 
The rear part of the forward upper jaw segment 21 constitutes a fork 21a, 
while the forward part of the rear upper jaw segment 22 is formed with a 
tongue or projection 22a configured to fit into said fork 21a. 
The fork 21a has a pair of bolt holes 23,23 formed in a vertical row, while 
the projection 22a is provided with two pairs of bolt holes 24,24 and 
25,25 disposed in a first row 24a and a second row 25a, respectively. 
These pairs of bolt holes 23,23,24,24 and 25,25 are respectively disposed 
at the same pitch so that the fork 21a and projection 22a may be rigidly 
connected to each other by means of a couple of bolts 26. 
As illustrated, the first row 24a of bolt holes 24,24 is inclined forward 
with respect to the second row 25a of bolt holes 25,25 so that the 
downward imaginary extension of said first row 24a and that of said row 
25a intersect with each other. In this arrangement, as the bolts 26,26 set 
into the holes 25,25 in the second row 25a are lined up with the bolt 
holes 23 of the fork 21a and threaded tight, the forward end of the upper 
jaw 4 may open with respect to the lower jaw 1 to the maximum degree of 
opening L.sub.1 as shown in FIG. 3. 
On the other hand, as the bolts 26,26 set into the holes 24,24 in the first 
row 24a are lined up with the bolt holes 23,23 of the fork 21a and 
threaded tight, the forward end of the upper jaw 4 may open with respect 
to the lower jaw 1 to the maximum degree of opening L.sub.2 as shown in 
FIG. 4. The relationship of said maximum degrees of opening is L.sub.1 
&gt;L.sub.2. 
Thus, when the shear of the invention is set to the maximum degree of 
opening L.sub.1 as shown in FIG. 3, it can be used to shear the 
reinforcing steel of a reinforced concrete building. On the other hand, 
when it is set to the maximum opening L.sub.2 as shown in FIG. 4, the 
shear can be used to grip and shear the steel member lain on the ground, 
for instance. 
It should be understood that while said projection 22a was described above 
as having bolt holes in two rows 24a ,25a , it may be provided with bolt 
holes in 3 or 4 rows. 
A second embodiment of the present invention is now described with 
reference to FIG. 5. The parts corresponding to those of the first 
embodiment are not described and only the difference from the first 
embodiment is described below. 
As shown in FIG. 5, the forward upper jaw segment 21 is connected to the 
rear upper jaw segment 22 in a stepped arrangement 27, instead of the 
fork-and-tongue arrangement described for the first embodiment. The 
arrangement of bolt holes is the same as in the first embodiment. By this 
arrangement, too, the object of the invention can be effectively 
accomplished. 
The steel shear of the present invention can be used not only in the 
demolition of buildings but also in the demolition of chemical plant 
pipelines, automobiles and so on. 
Since, in the present invention, the hydraulic cylinder for driving the 
upper jaw is disposed in a substantially vertical position, the shear as a 
whole can be provided in a compact form. Moreover, since this shear is 
swingable, shearing can be performed in the optimum position. Installation 
of a hydraulic cylinder in a vertical position would limit the maximum 
opening of the upper jaw. However, since the upper jaw is divided into two 
segments which can be connected by bolts in a choice of positions in the 
present invention, the shear of the invention provides for a sufficiently 
large opening of the jaws. Moreover, the jaw opening is adjustable to cope 
with varying sizes of shearing loads.