Diaphragm assembly

A diaphragm assembly for servo motors has been provided wherein a pair of backing elements have opposed portions acting on opposite sides of a diaphragm assembly and are held in fixed relationship to each other through the means of a sonic weld located at a point remote from the diaphragm to provide a leak-proof diaphragm assembly which lends itself to ready modification to accept valves or diaphragms to change the operating characteristics for different applications.

This invention relates to vacuum motors and more particularly to a 
diaphragm assembly for such motors. 
In the automotive field alone a large variety of small vacuum motors are 
used for various controls such as heater and air conditioning vents and 
choke controls for the carburetor of internal combustion engines, for 
example. 
Each of such vacuum motors is slightly different for its different 
applications with some employing control valves, delay valves, filters or 
spring loaded lost motion devices or any combination of such elements as a 
consequence of which the structures of the servo motors vary substantially 
from each other to accommodate such elements. Also typically such vacuum 
motors employ a diaphragm between stamped metal plates which are fastened 
together in a variety of ways but which usually are subject to leakage. 
It is the object of this invention to provide a diaphragm assembly for 
vacuum motors in which the same assembly is easily modified to accept 
various forms of filters, output members, valves and the like. 
Another object of the invention is to provide a diaphragm assembly for 
vacuum motors wherein the diaphragm and backing elements form an assembly 
resisting leakage. 
Still another object of the invention is to provide a diaphragm assembly 
for servo motors in which the assembly is easily modified to receive 
valves, filters and output members of a variety of configurations. 
A further object of the invention is to provide a diaphragm assembly in 
which the diaphragm and backing elements are fused together by sonic 
welding at a point remote from the diaphragm. 
The objects of the invention are accomplished by a servo motor having a 
housing in which a diaphragm assembly is disposed to divide the housing 
into a pair of chambers. The diaphragm assembly includes a pair of backing 
elements disposed at opposite sides of the diaphragm with one of the 
backing elements having a portion protruding through the diaphragm and the 
other of the backing elements having an axially extending portion forming 
a recess slidably receiving the protruding portion. The backing elements 
have opposed flanges that sealingly engage oppositely facing annular 
portions surrounding the opening in the diaphragm and the backing elements 
are held rigidly relative to each other by being fused together at a point 
spaced from the diaphragm in a manner such that the heat required for 
fusion does not affect the diaphragm and the flanges are maintained in 
sealing engagement with the opposed annular portions of the diaphragm.

The diaphragm assembly embodying the invention is designated generally at 
10 and is disposed within a servo motor 11 having a housing 12. As seen in 
FIG. 2, the diaphragm assembly 10 includes a diaphragm 14 having an outer 
annular flange 16 clamped in sealing relationship to flanges 18 and 20 of 
cup shaped front and rear housing covers or members 22 and 24, 
respectively. 
In addition to the diaphragm 14, the diaphragm assembly 10 includes a pair 
of backing elements 26 and 28 which are made of plastic material and are 
disposed at opposite sides of the diaphragm 14. The backing element 28 has 
a generally tubular portion 30 which protrudes through an opening 32 in 
the diaphragm 14. Extending radially outwardly form the tubular portion 30 
is a flange 34 which engages one side face of the diaphragm 14. An annular 
wall 36 is formed coaxially with the tubular portion 30 and extends in an 
opposite direction away from the flange 34. 
The tubular portion 30 which protrudes through the diaphragm 14 is received 
in a stepped bore 38 formed in the front backing element 26. The front 
backing element 26 is made of the same plastic material as the rear 
backing element 28 and has a flange 40 coextensive with and at the 
opposite side of the diaphragm from the flange 34. An auxiliary housing 
portion 42 extends axially to one side of the flange 34 and a portion of 
the bore 38 formed therein acts with the interior of the tubular portion 
30 to form a recess 44 which slidably receives an output member or stem 
46. The stem 46 protrudes through an opening 48 in one end of the axially 
extending portion 42. A spring 50 is disposed in the recess 44 and has one 
of its ends acting against a shoulder 52 and its other end acting against 
an annular stop member 54 formed integrally with one end of the stem 46. 
The spring 50 acts to urge the stem 46 to the right as viewed in FIG. 2. 
The exterior end 56 of the stem 46 protruding from the axially extending 
portion 42 is adapted to be connected to various controls. 
The annular wall 36 forming part of the rear backing element 28 acts as a 
guide for a spring 58 having one end reacting against the wall of the rear 
housing cover 24 and the other end acting against the flange 34. 
The opposed flanges 34 and 40 at opposite sides of the diaphragm 14 are 
held in sealing engagement with the diaphragm by fusing the forward and 
rearward backing elements 26 and 28 by sonic welding at an annular contact 
line indicated at 60. This serves to hold the backing elements 26 and 28 
permanently connected to each other without requiring any additional 
openings or the like in the diaphragm. Sealing is further enhanced by an 
annular rib 62 formed in the diaphragm 14 which fits into a complementary 
groove 64 formed in the flange 34. Fusion at the contact line 60 is 
accomplished by sonic welding by positioning a sonic welding head 66 as 
seen in FIG. 3 at the inclined portion 68 of the axially extending portion 
42. The sonic waves are directed through the plastic material forming the 
forward backing element 26 and causes a permanent bond to be made between 
the tubular portion 30 and the internal wall of the step bore 38 of the 
forward backing element 26. During such sonic welding temperatures to the 
order of 400.degree. F. are generated which normally would melt the 
exterior surfaces of the plastic parts forming the forward backing element 
26. However, in the present instance the plastic material includes 
filaments of fiberglass uniformly distributed throughout the plastic. The 
fiberglass elements not only add to the strength and rigidity of the parts 
but also act to convey heat from the exterior surface to the interior 
surface of the axially extending housing portion 42 so that a proper 
fusion or bond can be formed at the annular contact line 60. 
In the servo motor 11 just described, the diaphragm assembly 10 divides the 
housing 12 into forward and rearward chambers 70 and 71, respectively. A 
wall 72 is formed between the recess 44 and a cavity 74 defined by the 
annular wall 36. Admission of vacuum pressure to the chamber 71 formed at 
one side of the diaphragm 14 results in movement of the diaphragm assembly 
10 to the left as viewed in FIG. 1 because of atmospheric pressure which 
is maintained constantly in chamber 70 through opening 75. The resultant 
differential pressure on diaphragm assembly 10 moves it to the left moving 
with it any links or other instrumentalities connected to the end 56 of 
the stem 46. If the load of the instrumentality exceeds the force exerted 
by the spring 50 the spring 50 will first compress permitting the stem 46 
to move in the recess 44 to provide a lost motion connection. The 
compression spring 50 can be selected of a size to provide the desired 
opposition for a variety of loads depending on the application for the 
servo motor 11. 
Referring now to FIG. 3 a modification of the invention is shown in which a 
valve assembly 76 is disposed to control passage of fluid pressure between 
the chambers 70 and 71 at opposite sides of the diaphragm 14 and through 
the wall 72. In this instance an opening 78 is formed in the wall 72. The 
opening 78 is surrounded by an annular shoulder or recess 80 which acts as 
a seat for an O-ring 82. The O-ring 82 and annular recess 80 are covered 
by a temperature responsive bi-metallic element of concavo-convex 
formation designated generally at 84. The disc 84 is held in position by a 
tubular element 86 pressed into the recess 74 to limit outward movement of 
the disc 84. The temperature responsive disc 84 is such that at lower 
temperatures the disc retains the shape illustrated in the drawings. Under 
such conditions fluid exchange through the opening 78 between the chambers 
is relatively unrestricted. As the temperature increases the disc 84 tends 
to assume a flat configuration which brings it into contact with the 
O-ring 82 and obstructs the free passage of air between the chambers. As a 
result the application of vacuum to the left chamber 71 at low 
temperatures permits vacuum communication with the other chamber 70 and to 
the atmosphere through the opening 48 around the axial extending portion 
42. When temperature increases, such interchange of fluid is interrupted 
and the establishment of vacuum in the chamber 71 to the left of the 
diaphragm 14 causes movement of the diaphragm assembly 10 to the left 
pulling with it the stem 46. 
Referring now to FIG. 4, a further modification of the invention is shown 
in which the disc 84 is provided with a restricted opening or bleed 
orifice 88. When provided with this element and after the temperature is 
elevated to a predetermined level, the servo motor 11 permits relatively 
instantaneously actuation of the diaphragm assembly to move it to the 
left. However, as air passes through the bleed orifice 88 from the recess 
74 to the recess 44 and the fluid pressures in the two recesses become 
equalized, the diaphragm assembly 10 returns to the right to resume its 
normal position. This permits the device to be operated with a delay which 
can be of utility in controlling carburetors in which it may be desirable 
to delay operation of a control until engine temperature of a selected 
degree is achieved. Bi-metal discs 84 commercially available in a wide 
variety of sizes and temperature responsive levels so that the desired 
operation and delay may be easily selected. 
If desired, the orifice 88 of the disc element 84 can be fitted with a plug 
90 as seen in FIG. 5. In that case, the servo motor 11 will operate in the 
same manner as the arrangement illustrated in FIG. 3. 
As seen in FIG. 4, it is possible to provide the cavity 74 with a filter 
element 92 held between a tubular valve retainer 94 and a ring 96 both 
press fit into the bore of the cavity 74. The filter 92 prevents dust or 
particles of material from reaching the valve surfaces and orifices to 
insure proper operation. 
A diaphragm assembly for servo motors has been provided wherein a pair of 
backing elements have opposed portions acting on opposite sides of a 
diaphragm assembly and are held in fixed relationship relative to each 
other through the means of sonic welding to provide a leak-proof diaphragm 
assembly. The backing elements are formed of a plastic material which 
contains uniformly distributed filaments of fiberglass acting to 
distribute heat from the surface of the plastic elements to the interior 
at a point where the surfaces of the pair of backing elements are adjacent 
to each other and form a point of fusion. The diaphragm assembly lends 
itself to ready modification to accept valves or diaphragms to change the 
operating characteristics for different applications.