Window operator

A casement and awning window operator consisting of four parts, a top cover, a base, a worm gear receivable in a pocket on the base and top and a geared actuating arm engaging the worm gear having an integral arm extending out of the operator. The cover is secured to the base by an adhesive applied to matching surfaces of the cover and base trapping the worm gear therein. The cover and base are made from two plastic halves in a generally horizontal parting plane thus presenting a large adhesive contact area in a plane putting the contact surfaces in shear and allowing insertion of the gear and arm prior to assembly. The cover and base may have molded parts providing a spring-like effect to control the friction of the operator to prevent it from rotating out of a set position.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The invention relates to window operators; and, more particularly, to an 
operator for opening and closing vented windows. 
2. Background Information 
Rotary operators on casement and awning windows are generally manufactured 
from metal or stainless activating arms, including a heat treated worm 
gear, all mounted in a zinc die cast housing. 
The zinc housing is expensive to manufacture, particularly in the 
preparation and painting thereof. It offers poor wear characteristics on 
the worm gear thrust surfaces, and it is highly corrosive, particularly in 
seaside salty environments, where salt and moisture cause electrolytic 
corrosion between the zinc and other metal components. It is not uncommon 
for an operator to fail in less than a year in "salt moist" environments. 
Another problem with rotary operators, as discussed in U.S. Pat. No. 
4,505,601 to Sandberg, et al., is the difficulty in obtaining the proper 
amount of controlled friction in the mechanism itself so that buffeting 
winds on a window panel do not cause the operator to gradually rotate out 
of set position. 
Sandberg et al. accomplishes this by screwing in a retaining plug against 
the end face of the worm gear, in between which is sandwiched a bellville 
or bent washer. The adjustment of the retaining plug acts to flatten out 
the bellville washer causing a controlled frictional adjustment after 
which the plug is staked in place by deforming the die cast housing into 
machined recesses in the retaining plug, thereby preventing further plug 
rotation. Such metallic parts may fail in "salt moist" environments or at 
least become less efficient. 
There is thus a need for a casement and awning window operator that 
eliminates the corrosion encountered in such prior art operators and 
reduces the number of parts. Such an operator should eliminate the 
electrolysis encountered in such prior art operators and eliminate the 
frictional problems associated with the steel to zinc contact in such 
operators, and be less expensive to manufacture. An improved operators 
should work efficiently in "salt moist" environments to retain the 
operator in a set position. 
SUMMARY OF THE INVENTION 
It is an object of this invention to provide a casement and awning window 
operator that eliminates the corrosion encountered by such operators, 
particularly in seaside salty environment. 
It is another object of this invention to provide a casement and awning 
window operator consisting of only four parts. 
It is still further an object of this invention to provide a casement and 
awning window operator that eliminates electrolysis and frictional 
problems between the parts thereof. 
It is still further an object of this invention to control the friction of 
the operator so that it does not rotate out of a set position when the 
window panel is affected by buffeting winds. 
These and other objects are preferably accomplished by providing a casement 
and awning window operator consisting of four parts, a top cover, a base, 
a worm gear receivable in pockets in the base and top cover and a geared 
actuating arm engaging the worm gear having an integral arm extending out 
of the operator. The cover is secured to the base by an adhesive applied 
to mating surfaces of the cover and base trapping the worm gear and 
actuating arm therebetween. The cover and base is made from two plastic 
halves in a generally horizontal parting plane thus presenting a large 
adhesive contact area in a plane putting the contact surfaces in shear and 
allowing insertion of the gear and arm prior to assembly. In one 
embodiment of the invention, a spring-like effect is carried out by parts 
molded in worm gear pocket to control the friction of the operator to 
prevent it from rotating out of a set position.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring now to FIG. 1 of the drawing, a hinged window operator 10 is 
shown in exploded view consisting of only 4 parts, a top cover 11, a base 
12, actuating arm 13, and a worm gear 14. 
Operator 10 is shown in partially assembled view in FIG. 2 and final 
assembled view in FIG. 3. Thus, as seen in FIG. 1, operator 10 includes a 
generally flat rectangular cover 11 having a raised portion 15 forming an 
arch along one side thereof extending substantially transverse to the 
longitudinal axis of cover 11. 
Base 12 is also generally rectangular and flat having a main body portion 
18 and an integral flat flange portion 19, also generally flat and 
rectangular, extending along one elongated side of main body portion 18. A 
peripheral upstanding wall 20 extends along both sides 20, 20' of main 
body portion 18 and the front 20" thereof (opposite flange 19). Flange 19 
has a plurality of spaced apertures 21 therethrough for securing flange 19 
in a desired location. A generally cylindrical pivot pin 22 is provided 
upstanding from the surface 23 of main body portion 18. 
An upstanding wall portion 24 is also provided on surface 23 spaced from 
side 20' extending from the intersection of flange 19 and main body 
portion 18 to a raised portion 25. Raised portion 25 has an inner cavity 
26 between front wall portion 27 and rear wall portion 28. A like mating 
cavity 26a is formed in top cover 11 (see FIG. 4). As seen in FIG. 1, an 
opening 29 leads into cavity 26 and bearing surfaces 30, 31 are provided 
at the upper ends of front and rear wall portions 27, 28, respectively. As 
seen in FIG. 1, cavity 26 slopes from the front to the rear as shown (wall 
portion 27 being higher than wall portion 28). 
Actuating arm 13 has an elongated arm portion 32 which may have an opening 
33 at the terminal end thereof for coupling the same to suitable window 
attachment mechanism (not shown) as is well known in the art. Arm 13 has 
an integral rounded tooth-geared portion 34 having an aperture 35 
therethrough for receiving pin 22 therein as seen in FIG. 2. 
Worm gear 14 includes an elongated shaft 36 having an integral tapered 
portion 37 and an integral worm gear portion 38. Shaft 36 also has a 
spline portion 39 adapted to mate with the socket 100 of a crank handle 
101 as seen in FIG. 4. 
As seen in FIG. 4, worm gear 14 is mounted onto base 12 by placing worm 
gear portion 38 into cavity 26 with journal portion 37A resting in bearing 
surface 30 in front wall 27 and the bearing journal end 41 of worm gear 14 
resting in bearing surface 31 of rear wall 28. 
Lower cavity 26 and bearing surfaces 30, 31 are thus duplicated in the top 
cover 11 providing upper cavity 26a and bearing surfaces 17, 17a to trap 
worm gear 14 therein. Bearing surfaces 30 and 17 act to capture the worm 
journal 37a at the outside end whereas surface 31 interacts with a like 
surfaced 17a in the cover 11 to capture the inner journal 41. 
Actuating arm 13 is mounted on base 12 by means of pin 22 being receivable 
in opening 35 in arm 13 with the gears of geared portion 34 engaging in 
meshing relationship with worm gear portion 38. The arm 32 extends 
rearwardly of base 12. The upper end 102 of pin 22 is receivable in a hole 
103 in cover 11 as seen in FIG. 5. This adds strength to the structure. 
Glue or any other suitable adhesive is now applied to all contacting 
surfaces of cover 11 and base 12, such as the upper surfaces of peripheral 
walls 20, 20', 20", 24, 25, and 25A. Cover 11 is now placed on top and 
secured thereto, the shaft 36 of worm gear 14 extending outwardly as 
shown. The worm gear 14 is journalled in the mating surfaces as discussed. 
A clearance area 104 is provided between worm gear 14 and the wall of 
cavity 26a as seen in the final assembly in FIG. 4. 
Portion 39 of worm gear 14 may be quickly and easily coupled to crank 
handle 101 for rotating the same. Aperture 33 allows arm 13 to be coupled 
to any suitable window attachment mechanism, as, for example, the links 
coupled to arm 20 via hole 23 disclosed in U.S. Pat. No. 4,037,483. 
It can be seen that my invention is directed to a window operator 
consisting of only four parts, two mating housing parts (cover 11 and base 
12), which may be molded from plastic, and worm gear 14 (which may be of 
bronze or heat treated stainless steel) and arm 13 (which may be of 
stainless steel). Such a combination eliminates corrosion by substituting 
high performance plastic for the zinc normally used in prior art window 
operators. The device is manufactured in two halves (parts 11 and 12) in a 
generally horizontal parting plane as indicated by arrows x and y in FIG. 
4 and z n FIG. 5. This accomplishes two important things: 1) the parting 
plane, which is designed for adhesive assembly, presents the largest 
possible adhesive contact area in a plane that puts the contact surfaces 
in shear (as opposed to tension) so that the operating forces (separation 
forces of the worm gear 14 and tooth gear 34 of the arm 13) are 
distributed in a shear manner as opposed to the weaker tension manner, 
i.e., if the part were split in a vertical plane; b) the longitudinal 
split allows for the insertion of the worm gear 14 and the operating arm 
13 prior to assembly. This in turn eliminates the need for a secondary arm 
pivot pin assembly since pin 22 may be part of the molded housing 12, and 
it eliminates the need for a worm gear retaining plug as in prior art 
devices and all the machining operations associated therewith (for 
example, see U.S. Pat. No. 4,505,601 to Sandberg et al.). The precision 
pocket or cavity 26, which may be molded on base 12 and the mating cavity 
26a in top 11, that receives the worm gear 14, offers plastic thrust 
surfaces for the worm gear 14. Plastic to metal contact of worm gear 14 
and cover 11 and base 12 eliminates electrolysis and eliminates the 
frictional problems associated with steel acting against zinc as in 
certain prior art window operators. 
Furthermore, the plastic housing parts 11, 12 may be molded in any color, 
will not chip as paint will, and eliminate all the secondary operations 
normally performed to a prior art zinc die cast part . . . i.e., 
deflashing, tumbling, surface etching and cleaning, priming and painting. 
A two part plastic housing, as parts 11, 12, is designed for adhesive 
assembly that drastically reduces manufacturing cost and assembly time 
while improving performance, long term appearance and eliminates 
corrosion. 
As seen in FIG. 6, wherein like numerals refer to like parts of FIG. 4, 
upper top cover 11 and base 12 are molded so that the receiving pocket for 
the worm gear portion 38 of worm gear 14 is too small in length so that 
the worm gear portion 38 must be forced radially into such smaller space. 
The raised portion 15 of top cover 11 and end wall 27 of base 12 are 
molded with two vertical slots 201, 202 (FIG. 7) on opposite sides of 
bearing surface 30 (in base 12) and two vertical slots 203, 204 on 
opposite sides of bearing surface 17 (in top cover 11). These slots 201 to 
204 act to partially isolate the center portions between the slots. These 
center portions are molded slightly thicker on the inside at thickened 
portions 200, 205--see FIG. 6--(facing cavity 26) which create an 
interference with worm gear portion 38 as discussed above. Since the 
interference is created only by the thickened portions 200, 205 between 
slots 201 to 204, these thickened portions 200, 205 allow the center 
portions between slots 201 to 204 to bend outwardly as the worm gear 
portion 38 is forced into the seated position shown in FIG. 6. The worm 
gear portion 38 is thereby captured axially into the spring like action 
provided by the thickened portions 200, 205 and the center portions 
between the slots 201 to 204. 
It is noted that ordinary plastics have the tendency to creep under 
pressure or load. That is, they back away from a constant force over time, 
thereby losing their original configuration and lose spring tension over 
time. However, glass fiber may be added into the plastic formulation prior 
to molding thereby creating a permanent memory in the plastic fiberglass 
matrix thereby creating the permanent spring effect required. 
The proper spring effect can be manipulated by 1) varying the percentage of 
glass fiber content in the plastic; 2) varying the length of the glass 
fibers; and 3) varying the geometry of the length and thickness of the 
center portions between the slots and the thickened portions. This 
embodiment results in an operator in four parts that does not require 
mechanical procedures and adjustments of various machine components as 
does the apparatus in U.S. Pat. No. 4,505,601. 
It's also important to note that the glass fiber content of the plastic 
provides substantial stiffness and strength to the housing itself. This is 
necessary and desirable especially when an open window comes under strong 
gusty wind loads. Very recent state of the art in plastics sees low cost 
plastics that previously could not withstand high working loads; now, with 
the addition of glass fiber, one is able to replace metal components at a 
relatively competitive price. Such glass fibers could of course be 
formulated into the plastic in either embodiment of the invention. 
It can be seen that I have disclosed a window operator that is most useful 
in coastal area (salt) where conventional window operators having bi-metal 
contact areas deteriorate rapidly due to electrolysis. My invention has 
only one metal to metal contact area (the engagement of the worm gear to 
the geared actuating arm). In order to minimize corrosion at that point, 
the worm gear may be made from bronze and the arm may be made from 300 
series stainless steel. Bronze and 300 series stainless have minimal 
electrolysis properties and both metals are corrosion proof on their own. 
Only the worm gear and the geared arm require machining; the housing 
requires none. All prior art window operators contain more than four 
components and most operators contain many more machined components adding 
substantial cost and corrosion points. 
The window operator disclosed herein functions more smoothly and with less 
force than other operators. The worm gear bearing journals and the thrust 
faces act against the plastic of the housing. This frictional relationship 
of metal against plastic is much better than metal against metal 
especially when lubrication becomes depleted. Window operators of the type 
discussed herein are highly engineered apparatuses that will see 
intermittent high load situations and marginal lubrication conditions over 
their service lives. The window operators disclosed herein solve the 
problems encountered in use in coastal areas at relatively low cost. 
Although a particular embodiment of the invention has been discussed, 
obviously variations thereof may occur to an artisan and the scope of the 
invention should only be considered to be limited by the scope of the 
appended claims.