U.S. patent application number 10/291131 was filed with the patent office on 2004-05-13 for pullout spray head with pause button.
Invention is credited to Malek, Michael L., Tucker, W. Randall.
Application Number | 20040088786 10/291131 |
Document ID | / |
Family ID | 32107654 |
Filed Date | 2004-05-13 |
United States Patent
Application |
20040088786 |
Kind Code |
A1 |
Malek, Michael L. ; et
al. |
May 13, 2004 |
PULLOUT SPRAY HEAD WITH PAUSE BUTTON
Abstract
A spray head for a faucet or the like has a wand body defining a
flow path from an inlet to first and second outlets. Diverter seats
are provided so a face seal on a diverter spool can direct flow to
the first or second outlet. The spool is positioned by a trigger
acting on cam surfaces formed on a toggle. A spring biases the
toggle to one of two stable states. Movement of the spool by the
trigger causes the toggle to change states so subsequent actuation
of the trigger causes the spool to move in the opposite direction.
The wand body also has a pause button that reciprocates in a
chamber that is part of the flow path. The chamber includes a valve
seat and the pause button has a spool having a face seal that is
engageable with the valve seat to shut off flow through the spray
head. A return spring causes separation of the pause button's face
seal upon release of pressure on the pause button. The pause
button's seals in the chamber are arranged to have equal diameters
and thus provide balanced hydraulic forces on the spool.
Inventors: |
Malek, Michael L.; (North
Olmsted, OH) ; Tucker, W. Randall; (Oberlin,
OH) |
Correspondence
Address: |
COOK, ALEX, MCFARRON, MANZO, CUMMINGS & MEHLER LTD
SUITE 2850
200 WEST ADAMS STREET
CHICAGO
IL
60606
US
|
Family ID: |
32107654 |
Appl. No.: |
10/291131 |
Filed: |
November 8, 2002 |
Current U.S.
Class: |
4/677 |
Current CPC
Class: |
E03C 1/0404 20130101;
E03C 2001/0415 20130101; E03C 1/0409 20130101; B05B 1/1618
20130101 |
Class at
Publication: |
004/677 |
International
Class: |
E03C 001/04 |
Claims
We claim:
1. A spray head for discharging water, comprising: a body having an
inlet and at least one outlet, the body having walls which define a
water flow path from the inlet to the outlet and including a main
path and pause chamber; a valve seat formed in the pause chamber; a
spool movably mounted in the pause chamber and actuatable between
an open position and a closed position, the spool being pressure
balanced so that actuation force is independent of water pressure;
a face seal attached to the spool, the face seal being engageable
with the valve seat when the spool is actuated to the closed
position to block water flow through the water flow path.
2. The spray head of claim 1 further comprising first and second
seals attached to the spool on opposite sides of the face seal, the
first and second seals having substantially equal outer diameters
to maintain pressure balancing of the spool.
3. The spray head of claim 2 wherein the pause chamber has upper
and lower portions, the upper portion having a greater diameter
than the lower portion, said upper portion receiving a spool guide
in sealing engagement therewith, the spool guide having a central
bore of a diameter substantially equal to that of the lower
portion, the first seal being engageable with the spool guide bore
and the second seal being engageable with the lower portion of the
pause chamber.
Description
BACKGROUND OF THE INVENTION
[0001] This invention relates to faucets and is particularly
concerned with a faucet having a pullout spray head or wand
connected to a flexible water supply tube. The spray head can be
mounted on a fixed base unit or it can be detached from the base
unit and pulled out to allow a user to direct water to any desired
location.
[0002] It is often desirable to provide a spray head with more than
one water delivery mode. Multiple delivery modes may include a
spray mode and a stream mode. In the spray mode water is discharged
in a relatively wide spray pattern comprising a large number of
small, individual streams. In the stream mode water is discharged
in a single, relatively narrow, concentrated stream. Multiple modes
of this type are particularly useful in kitchen faucets, although
their use is not limited to kitchens. Lavatories, showers or any
other faucet, including a garden hose, may benefit from this
feature.
[0003] Multiple water delivery modes are commonly provided in fixed
faucets by means of a nozzle having a push-pull feature that
switches the nozzle between spray and stream modes. Pullout spray
heads are known that require the user to hold a button in a
depressed state to get an alternate mode. See U.S. Pat. No.
6,370,713. Other spray heads require that separate buttons and/or
levers be pushed to change from one mode to another. Examples are
U.S. Pat. Nos. 6,220,297, 5,858,215 and 6,290,147. Still other
designs use a rocker switch that require opposite ends of the
rocker to be pushed to change modes. Non-pullout faucets sometimes
change modes by requiring a lever to be slid or twisted, or by
requiring opposing actions on a slide. Shower spray heads are known
that produce different spray patterns by requiring a dial type
device or a lever to be twisted in different directions to change
spray modes. Garden hose nozzle designs also typically have a dial
type device for changing spray modes.
[0004] One difficulty that can occasionally arise in the use of
pullout spray heads is the need to momentarily shut off the water
or alter its temperature. If the user is grasping the spray head in
one hand and has another item, such as a pan or dish, in the other
hand then there is no convenient way to manipulate the water
controls. The choices are to put the pan or the spray head down,
return the spray head to its base, or try to manipulate the
controls with a portion of a hand that is still grasping an item.
For example, a user might try to manipulate the controls with the
palm of a hand while the fingers of that hand retain the spray
head. Perhaps an ambitious user might try to actuate the water
controls with an elbow. Obviously none of these are convenient.
What is needed is a water control incorporated into the spray head.
The present invention provides such a control in the form of a
pause button.
SUMMARY OF THE INVENTION
[0005] The present invention is concerned with a pullout spray head
which provides multiple water discharge spray patterns or modes and
which permits momentary shut off of water flow with a pause button.
The mode is selected by means of a single action at a single point
of actuation. The user is not required to hold the actuating device
in place while using the various modes. The mode is changed simply
by pressing the same button, in the same direction, with each
successive actuation of the button changing the discharge mode. The
spray head will remain in the selected mode until another actuation
of the button or until the water is turned off, at which time the
spray head reverts to a home position or mode.
[0006] The spray head of the present invention also includes a
pause button that momentarily interrupts the water while the pause
button is depressed. The button must be held in the depressed
position to keep the flow interrupted. Release of the pause button
reactivates water flow. The force necessary to actuate the pause
button is independent of the water pressure, within the limits of
normal household operating pressures (which range from about 10 psi
to 125 psi). The pause button is especially useful when the spray
head is pulled out because the primary on/off control valve may
often be an inconvenient distance from the spray head. The pause
feature is also useful in two-handle faucet designs where resetting
of the hot/cold ratio may also be inconvenient. The pause feature
is applicable to all discharge modes of the faucet.
BRIEF DESCRIPTION OF THE DRAWINGS
[0007] FIG. 1 is a perspective view of a single handle, high arc
pull down faucet incorporating the pullout spray head of the
present invention.
[0008] FIG. 2 is a schematic section through the faucet of FIG.
1.
[0009] FIG. 3 is an exploded perspective view of the pullout spray
head.
[0010] FIG. 4 is a top plan view of the wand body.
[0011] FIG. 5 is a side elevation view of the wand body.
[0012] FIG. 6 is an end elevation view of the wand body.
[0013] FIG. 7 is a bottom plan view of the wand body.
[0014] FIG. 8 is a section taken along line 8-8 of FIG. 6.
[0015] FIG. 9 is a section taken along line 9-9 of FIG. 6.
[0016] FIG. 10 is a section taken along line 10-10 of FIG. 6.
[0017] FIG. 11 is a top plan view of the trigger spring, on an
enlarged scale.
[0018] FIG. 12 is a section taken along line 12-12 of FIG. 11.
[0019] FIG. 13 is a front elevation view of the toggle wedge, on an
enlarged scale.
[0020] FIG. 13 is an end elevation view of the toggle wedge.
[0021] FIG. 15 is a section taken along line 15-15 of FIG. 13.
[0022] FIG. 16 is a bottom plan view of the toggle wedge.
[0023] FIG. 17 is a schematic vertical section through the spray
head assembly, showing the interaction among the trigger, diverter
and wand body.
[0024] FIG. 18 is a section through the spray head assembly,
showing the diverter in the spray mode position.
[0025] FIG. 19 is a section through the spray head assembly,
showing the diverter in the stream mode position.
[0026] FIG. 20 is a section through the spray head assembly,
showing the diverter in the stream mode position and the pause
button activated.
[0027] FIG. 21 is an enlarged section through the pause button
portion of the spray head.
[0028] FIG. 22 is an exploded perspective view of an alternate
embodiment of a spray head.
[0029] FIG. 23 is horizontal section through the spray head of FIG.
22.
[0030] FIG. 24 is a vertical section through the spray head of FIG.
22.
DETAILED DESCRIPTION OF THE INVENTION
[0031] FIGS. 1 and 2 illustrate a faucet generally at 10 which
incorporates the pullout spray head or wand of the present
invention. The faucet 10 includes a gooseneck spout 12 and a single
handle mixing valve 14, both of which are mounted above a deck,
which is shown schematically at 16. The pullout spray head 18 is
shown in its docked position at the distal end of the spout 12.
Below the deck are hot and cold water supply lines 20, 22, a mixed
water outlet pipe 24, a transfer line 26, and a mixed water inlet
pipe 28. A quick connect 30 is connected to the inlet pipe. A
flexible hose 32 is attached to the quick connect 30 and extends
through the hollow interior of the spout to join the spray head 18.
The hose has a weight 34 on it to assist in drawing the hose back
into the spout during docking.
[0032] FIG. 3 illustrates the pullout spray head 18 of the present
invention. The exterior components include a main cover 36, a
trigger cover 38, a ring 40 at the proximal end of the spray head
and a tip 42 at the distal end. As used herein proximal refers to a
position or direction toward the portion of the spray head nearest
the hose attachment point. Distal refers to a position or direction
toward the portion of the spray head nearest the water discharge
point. The exterior parts have suitable decorative finishes. The
ring 40 is sized to permit it to releasably connect to the end of
the spout 12 for the purpose of docking the spray head to the
spout. The main cover 36 has a slot 44 for receiving the trigger
cover 38. The trigger cover is made of flexible material and has a
trigger dome 46 and a pause dome 48.
[0033] The exterior components surround a wand body 50. Details of
the wand body are shown in FIGS. 4-10. The body has an arcuate
bottom wall 52 which joins two upstanding, flat side walls 53, 54.
The side walls have projecting tabs 55 that engage retention slots
in the trigger cover 38 to hold the cover in place. A floor 56
extends between the lower edges of the two side walls. Thus, the
floor 56 forms a chord across the arcuate bottom wall 52, as best
seen in FIG. 10. Together the bottom wall and floor define a main
water flow path 58. The ends of the side walls are joined by front
and rear transverse walls 60 and 62. The rear transverse wall 62
has a pocket 63 formed just above the floor. The front wall has a
bore 64 therethrough defined by a sleeve 66. The forward or distal
end of the sleeve defines a first diverter seat 68. There are also
two laterally extending, hollow embossments 69 (FIG. 9) on the
distal face of the front wall 60. These embossments have branch
passages 71 therein that are in fluid communication with the bore
64. The branch passages have openings in the sides of the body, one
of which is shown at 70 in FIG. 5. The openings 70 communicate with
V-shaped notches 72 cut into threads 74 formed on the exterior of a
threaded annular outlet wall 76. The outlet wall merges with the
front transverse wall 60 and the arcuate bottom wall 52, roughly at
the location of an O-ring seal 78.
[0034] At the proximal end of the wand body there is a threaded
annular inlet wall 80 defining an inlet 82. The hose can be
attached to the inlet wall. The inlet wall is surrounded by a
threaded outer sleeve 83 which may be used to attach the wand ring
40. The inlet wall 80 preferably may house a check valve 84 and a
screen washer 86 (FIG. 3). The inlet wall 80 merges with the bottom
wall 52, side walls 53, 54 and an upstanding interior wall 88 (FIG.
8). These walls, together with the proximal face of the rear
transverse wall 62 define a pause chamber 90. The pause chamber has
an axis that is generally perpendicular to that of the wand body
50. The pause chamber houses the pause button as will be described
below. A circular valve seat 92 is formed in the walls forming the
pause chamber. The interior wall 88 has a port 94 through it to
provide fluid communication from the inlet 82 to the pause chamber
90. It will be noted that the pause chamber also communicates with
the main flow path 58 and thus becomes part of the main flow
path.
[0035] Returning again to FIG. 3 and the distal end of the spray
head 18, the inner surface of the outlet wall 76 has an undercut 95
into which fits a poppet valve seat 96. This ring-shaped member has
a central opening 97. The V-shaped opening 97 provides a second
outlet from the body, the first outlet being the side openings 70.
A second diverter seat 98 is formed on the inner surface of the
poppet valve seat 96. An O-ring 100 placed about the outer
circumference of the seat 98 seals against the inner surface of the
outlet wall's undercut portion.
[0036] A spray former 102 is attached to the outlet wall 76. The
spray former has an outer annular skirt 104 with internal threads
that engage threads 74. It will be noted in FIG. 18 that the skirt
engages a lip on the interior of the wand tip 42 to hold the tip
against the wand cover 36. The junction between the skirt 104 and
the wand body is sealed by an O-ring 78. A radial end surface 106
extends from the outer skirt 104 to an inner annular ring 108 which
is attached to the end surface so as to be concentric with the
skirt. There is a gap between the inner ring 108 and the outer
skirt 104 which communicates with a plurality of small individual
outlet openings 110 through the end surface 106. These openings
produce the spray mode of the spray head 18.
[0037] The interior of the inner ring mounts an aerator 112. A face
seal 114 is placed between the aerator 112 and the distal radial
face of the poppet valve seat 96. This seal prevents leakage from
the opening 97 in the poppet valve seat to the gap between the
spray former's inner ring 108 and outer skirt 104. Thus, when the
spray head is in stream mode, water cannot find its way to the
spray mode openings 110. A cone spring 116 surrounds the aerator
and has its large end bottomed against the end surface 106 of the
spray former. The cone spring extends through the opening 97 in
poppet valve seat 96 to engage the diverter spool as will be
explained below.
[0038] The wand body 50 includes a cavity defined by the side walls
53, 54, floor 56 and transverse walls 62, 64. This cavity is
completely isolated from the water flow path. As seen in FIGS.
18-20 , a trigger, spring and diverter assembly are disposed in the
cavity. The diverter assembly includes a spool 118 that is slidably
mounted in the sleeve 66 and pocket 63. The spool carries a quad
cup seal 120 and a face seal 122. The face seal is engageable with
the first diverter seat 68 and the second diverter seat 98. The
other end of the spool has a pin 124 extending transversely through
the spool. The pin pivotally mounts a toggle 126 to the spool. In
this embodiment the toggle is in the form of a wedge.
[0039] Details of the toggle wedge 126 are shown in FIGS. 13-15.
The wedge has two sets of cam faces 128, 129 separated by a central
section 130. Two loops 131 underneath the cam faces have bores that
allow the loops to fully surround the pin 124. The cam faces have
grooves 133 in their undersides that partially receive the pin
therein. The cam faces 128, 129 in an end view of the wedge have a
triangular shape with relatively sharp lower corners as at distal
corners 132 and proximal corners 134.
[0040] A trigger spring 136 is also mounted in the wand cavity. As
seen in FIGS. 11 and 12, the spring has two elongated legs 138
joined at one end by an upstanding bail 140 and at the other end by
a U-shaped angled portion 142. The bail 140 straddles the pocket 63
while the angled portion fits over the spool 118. The legs 138 have
notches 144 that engage extensions 145 (FIGS. 4 and 8) on the inner
surfaces of side walls 53, 54 to fix the longitudinal position of
the trigger spring in the wand cavity. The floor 56 has
wedge-shaped protrusions 147 (FIGS. 4 and 8) adjacent the
extensions 145. The protrusions 147 engage the underside of the
legs near the notches 144 and act as fulcrums. When the trigger is
in place it presses down on the angled portion 142 distally of the
fulcrums with the result that the portions of the legs proximal of
the fulcrums (approximately from the notches 144 to the bail 140)
are spaced above the floor and are, in effect, cantilevered from
the fulcrums. This is best seen in FIG. 17. The legs also have
depressions or troughs 146 disposed generally in the vicinity of
the toggle wedge 126. The troughs are sized to enable them to be in
registration with one of the wedge corners. When that happens one
pair of cam corners will engage the legs while the other pair of
cam corners will be disengaged from the spring's legs 138. This
causes the toggle wedge to flip back and forth, as will be further
explained below.
[0041] The trigger is shown at 148. It is pivotally mounted to the
wand body by stubshafts 150 that extend into slots in the side
walls 54. One of the slots is shown at 152. The trigger includes a
pushbutton 154 disposed underneath the trigger dome 46 in the
trigger cover 38. Underneath the pushbutton are two spaced fingers
156. Each finger is engageable with one of the cam faces 128, 129.
The body of the trigger rests on the angled portion 142 of the
trigger spring and is biased upwardly by the angled portion.
Conversely, the angled portion is pressed down with the resulting
cantilevering of the legs as just explained.
[0042] Turning now to the pause button, this structure is best seen
generally at 158 in FIGS. 3 and 21. The pause button includes a
pause spool 160. The pause spool has a series of flanges which form
upper, intermediate and lower recesses 162, 164, 166. The upper and
lower recesses receive quad cup seals 168 while the intermediate
recess receives a face seal 170. The bottom of the spool 160 has a
bore 172 into which fits a spring 174. The spring bottoms on the
bottom wall which is vented to atmosphere by openings 175 (FIG. 7).
Similarly the top of the spool chamber is vented so there is no
build up of any air pressure on either side of the spool as it
moves up and down. A pause spool guide 176 rests in the upper end
of the pause chamber 90 and is sealed thereto by O-ring 178. A
flange 180 on the spool guide engages the top flange of the upper
recess 162 so as to limit upward motion of the pause spool 160. The
pause spool guide 176 is retained by a U-shaped stop clip 182 that
slides through slots 183 (FIG. 8) in the pause chamber walls. A
flexible cap 184 sits on top of the spool 160 and underneath the
pause dome 48 of the trigger cover 38.
[0043] It is pointed out that the flange outside diameters of the
upper and lower recesses 162, 166 are essentially the same. This is
important to maintain evenly balanced hydraulic forces on the pause
spool 160. The only unbalanced forces on the spool are those
applied by the spring 174 and the user. At the same time the face
seal 170 needs to be larger than the quad cup seals in order to
enable it to engage the seat 92. This creates an assembly problem
as you need to insert the pause spool with a larger central seal
into a chamber sized for engagement with two smaller quad cup seals
on either side of the larger seal. The pause spool guide solves
this problem. The upper portion of the pause chamber is enlarged to
allow passage of the face seal 170. Then the pause spool guide
fills in the extra space to allow the upper and lower quad cup
seals to be the same size. If the spool guide were integral with
the spool, the upper seal would have a greater area than the lower
seal and the hydraulic forces on the spool would not be balanced.
The separate pause spool guide resolves that issue as well as the
assembly problem.
[0044] The use, operation and function of the above embodiment are
as follows. Consider the pause button first. The normal condition
of the pause button 158 is shown in FIG. 21. The spring 174 urges
the spool 160 upwardly so the face seal 170 is spaced from the
valve seat 92. Water can flow from the inlet 82 through the port 94
into the pause chamber 90, past the seat 92 and into the main flow
path 58. Water pressure is present over the central portion of the
spool. Since the seals 168 have equivalent, or nearly equivalent,
pressurized areas, the hydraulic forces on the spool are balanced.
This allows the return spring 174 to push the spool to the open
position regardless of the water pressure. When a user wishes to
momentarily shut off the water, he or she presses down on the pause
dome 48, causing the spool 160 to move down and carry the face seal
170 into engagement with the valve seat 92. This condition is shown
in FIG. 20. Water can enter the upper portion of the pause chamber
but it cannot flow past the seat 92. This shuts off the water for
as long as the user holds down the pause button 158. When the user
releases the pause button, the spring 174 again raises the spool
160 which removes the face seal from the seat 92 and allows flow
again into the main flow path 58.
[0045] Looking now at operation of the diverter assembly, it will
be assumed for this discussion that the pause button is in the
normal, open position. The diverter switches flow between two water
delivery modes. In this case the modes are stream and spray,
although it could be otherwise. The diverter starts out in its home
position as shown in FIG. 19. Here the spool 118 is retracted so
the face seal 122 is engaged with the first diverter seat 68. This
cuts off flow into the sleeve 66 and thus flow to the branch
passage openings 70 is prevented. All the flow is directed out
through the poppet valve seat opening 97, into and then out of the
aerator 112. This is stream mode. Meanwhile the top of the toggle
wedge is leaning forwardly, i.e., toward the distal end of the
spray head. This is because the spring legs 138 are in contact with
the proximal wedge corners 134 while the distal wedge corners are
in the troughs 146 and are thus largely unsupported. The spring
legs 138 in this condition urge the wedge counterclockwise, as seen
in FIG. 17. The fingers 156 of the trigger 148 rest on the proximal
surfaces of the cam faces 128, 129.
[0046] When a user actuates the trigger by pushing down on the
trigger dome 46, the trigger pivots in a clockwise manner (as seen
in FIG. 17) about the stubshafts 150. The downward movement of the
fingers 156 on the cam surfaces causes the wedge and the spool 118
to slide forwardly. As the spool moves it carries the toggle wedge
with it but the trigger spring 136 remains longitudinally
stationary. As the wedge moves forwardly, the spring legs flex
downwardly as the distal wedge corners 132 drive up out of the
troughs 146 and onto the legs 138. At the same time the proximal
wedge corners 134 move out of engagement with the legs and into
registration with the troughs. Thus, when the trigger is released,
the legs act on the distal wedge corners to pivot the toggle wedge
126 clockwise. Now the top of the wedge leans toward the rear of
the spray head and the distal surfaces of the cam faces are aligned
with the trigger fingers.
[0047] At the same time as this motion of the wedge takes place,
the spool 118 has carried the face seal 122 into engagement with
second diverter seat 98 on the poppet valve seat 96, as shown in
FIG. 18. This is the spray mode. Water flow through the valve seat
96 is prevented by engagement of the face seal 122 and second
diverter seat 98. However, the forward movement of the spool has
removed the face seal from the first diverter seat 68 so water can
flow into the sleeve 66 and into the branch passages 71 in the
embossments 69 and from there out the openings 70. Water will
continue from there through the V-shaped notches 72 to the gap
between the spray former's outer skirt 104 and inner ring 108.
Water ultimately flows out the plurality of outlet openings 110 in
spray mode.
[0048] Subsequent actuation of the trigger will move the spool 118
rearwardly. Face seal 122 will then disengage the second diverter
seat 98 and reengage first diverter seat 68. At the same time the
spool will drive the proximal wedge corners 134 out of the spring
troughs 146 and up on to the legs 138. Simultaneously the distal
wedge corners 132 will be aligned with the troughs. With the distal
wedge corners thus unsupported, the legs will flip the wedge
counterclockwise so the top of the wedge leans forwardly once
again, readying the spool to shift to the opposite mode upon the
next actuation of the trigger. In this sense the spring legs 138
and troughs 146 can be considered an over-center spring. Moving the
wedge corners in and out of registration with the troughs in effect
moves them over the center position of the spring and causes the
state of the toggle to change.
[0049] It can be seen in FIGS. 18 and 19 that water pressure in the
main flow path will maintain the spool in whatever state it is
placed by the trigger. However, when water pressure is removed,
either by the pause button being actuated or the mixing valve 14
being turned off, the cone spring 116 will cause the spool 118 to
retract. The cone spring is selected so it is not strong enough to
overcome water pressure but in the absence of water pressure, it
will drive the spool to the home position.
[0050] An alternate embodiment of the spray head is shown generally
at 186 in FIGS. 22-24. This embodiment utilizes several components
whose functions are identical to those described above but they may
be shaped somewhat differently. These include a wand body 188 that
has a cavity 190, a main flow path 192 under the cavity and a first
diverter seat 194. A second diverter seat 196 is formed in spray
former 202. A wand cover 197 surrounds the body 188. A first flow
passage for stream mode extends through an aerator 198. A second
branch flow passage for stream mode is shown at 200 in FIG. 23. A
spray former 202 with 0rings 204 is also provided. The spray head
has a two-piece trigger mechanism including a trigger button 206
and a trigger lever 208. A spool driver 210 has first and second
cam faces 212 and 214. The spool driver 210 is guided in a channel
216 that is formed in the floor of the cavity 190. The mode is
toggled by the trigger button 206 being depressed which pushes the
trigger lever 208 on to one of the spool driver cam faces 212, 214.
The spool driver is connected to the end of a spool 218 in a manner
that allows the spool driver to pivot. As in the embodiment of FIG.
3, the spool 218 has an elastomeric face seal 220 that is
alternately engageable with one of the first and second diverter
seats 194, 196. The face seal 220 closes one water path through
aerator 198 when in engaging the second diverter seat 196 and
closes the other water path 200 when engaging the first diverter
seat 194. As mentioned, the spool driver 210 has two cam faces 212,
214, one that causes the trigger motion to move the spool driver
and spool into a spray position and one that causes the trigger
motion to move the spool driver and spool into the stream mode
position. Only one of the cam faces is aligned with the trigger
mechanism at a time. This alignment is done by the shaped channel
216 that guides and positions the spool driver cam faces
appropriately for returning to stream mode when the mechanism is in
the spray mode, and returning the mechanism to spray mode when in
stream mode. To position the cam faces appropriately it is
necessary that the trigger lever be free to pivot side to side so
that it maintains contact with the cam face as the spool driver
moves through the shaped channel.
[0051] In this embodiment the trigger lever 208 must center itself
to the ready position after it has pushed the spool driver to the
new mode position, and the trigger button 206 has been released.
One way to do this is with cantilevered leaf springs on either side
of the trigger lever that push it back to center when no other
force is on it. Another way of centering the trigger lever is to
shape the bottom pivoting portion of it and constrain the trigger
lever to within the trigger button. In this way when the trigger
button is released and the trigger lever rocks back, it is forced
to center itself.
[0052] Whereas the preferred form of the invention has been shown
and described herein, it should be realized that there may be many
modifications, substitutions and alterations thereto. For example,
there could be more than two water delivery modes. Preferably, one
of the modes is designated a default mode which the diverter take
up whenever the water is shut off. This is so a user will know what
to expect when the water is next turned on. Alternatively, a spray
head could have no default mode so whatever mode it was in when
water was shut off will be the one it is in when water is turned
back on. In the preferred embodiment there is a default mode and it
is the stream mode.
* * * * *