Hot water tank bracket assembly

A hot water tank bracket assembly for affixing the tank to the framing studs of buildings, thereby, providing a secure stable mount of the tank to the wall in the vent of a moderate or substantial sized earthquake. Preferably, the bracket assembly comprises a mounting bracket, a high-strength flexible strap to secure the water tank to the bracket, and mounting flanges which can be slid along the edge of the bracket to permit aligning of the mounting flanges to the framing studs. Additionally, the edge facing the bracket is arcuate in shape in order to receive and cradle a significant portion of the water tank periphery.

TECHNICAL FIELD 
The present invention relates, in general, to gasheated, hot water tanks 
typically employed in homes, commercial buildings, or the like, and more 
particularly, relates to an apparatus used for securing and mounting hot 
water tanks to the walls and framing studs of such buildings. 
BACKGROUND OF THE INVENTION 
In areas which experience earthquakes, a very high percentage of the number 
of fires which are caused by the quake are the result of gas-heated, hot 
water tanks which tip over during the earthquake. It has been estimated 
that as high as 90% of the house fires which occur are a direct result of 
water heater instability. 
Typically, water heaters are either not stabilized at all (other than by 
their plumbing), or they are mounted by plumber's strapping or L-shaped 
brackets to sheetrock, or occasionally framing studs, by a nail or screw. 
Moreover, the hot water tank is often placed on a pedestal or raised 
section of the flooring where such placement further increases the water 
heater's instability and susceptibility to tipping. Little in the way of 
code requirement for the securement of hot water tanks has been enacted. 
While plumber's strapping of L-shaped brackets have been adequate mounting 
devices during stable, nonearth movement conditions, various problems have 
occurred when such devices were exposed to the severe acceleration caused 
by a earthquake. Earthquakes often generate P-waves (rolling type 
compression waves) which travel along the surface of the earth's crust. 
These waves tend to sway objects from side-to-side and are generally the 
main cause of most building damage due to the earthquake itself. Likewise, 
the momentum of the water tank gained due to seismic accelerations, 
coupled with the fact that a filled 50 gallon hot water tank can weigh in 
excess of 500 pounds, has led to disastrous results. Under earthquake 
conditions, strapping frequently will go slack or experience a stress 
reversal which allows the water tank transverse or lateral momentum to 
build, and the increasing momentum pulls the nail or screw from the 
wallboard or breaks the strapping or brackets. Since brackets are often 
secured to the thin metal of the tank housing by screws, such fasteners 
also can pull out of the tank wall. Thus, as the acceleration becomes 
significant, prior water tank securement assemblies have typically failed 
under earthquake conditions. As already mentioned, this instability of 
gas-heated water tanks has resulted in fires and major gas leaks. 
Few, if any, attempts to lessen or overcome the problem of gas-heated, hot 
water tank instability have been made. The prior art has not addressed the 
peculiar environment inherent in an earthquake condition, nor has the 
prior art addressed the problem of the extreme mass of a hot water tank. 
What attempts have occurred have largely been based upon providing a 
separate enclosure for the water storing tank. Thus, Arzberger, U.S. Pat. 
No. 3,730,144, for example, discloses a hot beverage dispenser enclosed in 
a housing. The storage tank is secured via a bracket and a strapping means 
which is subsequently connected by a vertical stabilizing rod embedded in 
the base of the water tank. More importantly, Arzberger does not fasten 
the water tank to the housing nor does the bracket employed provide a 
versatile alignment means capable of securement to the varying locations 
at which framing studs may occur in a wall. Thus, the simplistic bracket 
and strapping means utilized in Arzberger is not adequate for the specific 
requirements of the present invention. 
There are other means for mounting tanks within enclosures in which straps 
and buckles are employed to secure the tank. One such securement means is 
disclosed in U.S. Pat. No. 3,805,988 to Walker et al. However, the 
assembly set forth is not suitable for mounting the type of heated water 
tanks used in homes and industries. The mounting means utilized in Walker 
is only sufficient for smaller portable tanks which are periodically 
removed and replaced. Walker does not have the versatility of aligning the 
means for attachment to the enclosure with the framing studs as required 
by the present invention. Furthermore, the strapping and buckle means 
supplied in Walker are more adequate for ease of removal. Thus, it follows 
that because of the inappropriate design and the excessive weight of a hot 
water tank, it would eventually pull free of the sheetrock under 
earthquake conditions. 
Finally, there are other securing methods which relate generally to 
strapping assemblies for hanging pipes. Typical of these systems are the 
pipe mountings disclosed in Loosdon and Norton, U.S. Pat. Nos. 4,768,741 
and 4,844,396, respectively. Both the strapping assemblies, however, are 
not suitable for use with large water storage tanks under earthquake type 
conditions. 
While the prior disclosures have been satisfactory for many applications, 
it has been found to be highly desirable to provide an assembly capable of 
securing a hot water tank of substantial mass to a stable structure, such 
as the framing studs of a building. 
Accordingly, it is an object of the present invention to provide a hot 
water tank bracket assembly which can withstand the substantial seismic 
accelerations common to moderated or large earthquakes. 
It is another object of the present invention to provide a hot water tank 
bracket assembly which provides a bracket suitable for placement 
juxtaposed a wall which simultaneously cradles the water tank for maximum 
stability, yet facilitates the removal and replacement of the water tank. 
It is yet another object of the present invention to provide a hot water 
tank bracket assembly which can be retrofit in existing installations for 
positive fastening of the tank to framing studs of a building. 
It is a further object of the present invention to provide a hot water tank 
bracket assembly which is durable, compact, easy to maintain, has a 
minimum number of components and is economical to manufacture. 
The apparatus of the present invention has other objects and features of 
advantage which will become apparent from and are set forth in more detail 
in the description of the Best Mode of Carrying Out the Invention and the 
accompanying drawing. 
SUMMARY OF THE INVENTION 
In summary, the hot water tank bracket assembly of the present invention is 
particularly suitable for use in any buildings such as homes, commercial 
buildings, industrial institutions or the like which are situated in 
unstable ground movement areas. During periods of ground instability, the 
bracketing designed in accordance with the present invention provides a 
slack-free cradle for the water tank and positively fastens it to the 
relatively stable framing studs. Unlike current mounting methods and 
techniques, only a virtual collapse of the adjoining framing studs will 
cause the water tank to topple. As will be described briefly here and in 
more detail hereinafter, the hot water tank bracket assembly of the 
present invention comprises a water tank mounting bracket, a flexible 
strapping material and movable mounting flanges for alignment and 
securement to the framing studs. Most preferably, the tank bracket, which 
contains an arcuate edge, substantially conforms to and mates with a 
significant portion of the water tank periphery. Additionally, the 
high-strength flexible strapping material is then tightly fastened to the 
bracket, thereby securing the bracket and strap assembly to the tank 
housing against movement relative to the housing. The mounting flanges are 
slidably mounted to the tank bracket. Once the location of a couple 
framing studs are established, the flanges are subsequently aligned and 
secured against movement to the bracket. Fasteners, such as lag screws, 
then are used to fasten the flanges, and thus the bracket assembly and 
tank, to the studs against transverse or lateral movement relative to the 
studs. Mounting these flanges to the framing studs result in a superior 
stabilization of the water tank unattainable from the current apparatus 
and techniques. 
The hot water tank bracket assembly of the present invention and the method 
in which it is installed will be described in more detail below in 
conjunction with the drawings.

BEST MODE FOR CARRYING OUT THE INVENTION 
Reference will now be made in detail to the preferred embodiments of the 
invention, examples of which are illustrated in the accompanying drawings. 
While the present invention has been described with reference to a few 
specific embodiments, the description is illustrative of the invention and 
is not to be construed as limiting the invention. Similarly, although 
primarily designed to stabilize water tanks from ground instability of the 
type usually experienced by both moderate and major earthquakes, the 
present invention may also be employed where any movements may be 
experienced such as by ocean vessels, severe vibratory areas due to 
machinery, explosions, or the like. Various modifications may occur to 
those skilled in the art without departing from the true spirit and scope 
of the invention as defined by the appended claims. 
Turning now to the drawings, wherein like components are designated by like 
reference numerals throughout the various figures. In FIGS. 1 and 2 a 
water tank, generally designated 21, is mounted to a corner wall structure 
using the bracket assembly, generally designated 22, of the present 
invention. As illustrated, hot water tank 21 is typically mounted 
proximate a corner of a small room or space in the home. Customarily, 
plasterboard sheets 23 and 25 are mounted to 2".times.4" frame members 27, 
29, 31 and 33. Tank 21 preferably is mounted in a somewhat spaced 
condition from the sheetrock panels 23 and 25 in order to enable plumbing 
of the same and to minimize heat transfer to the sheetrock. 
More particularly, in a typical installation tank 21 will include a gas 
inlet conduit 24 which is coupled to a gas burner (not shown) and an 
exhaust gas conduit 26 which communicates combustion gases to the exterior 
of the building. Also coupled to the tank 21 are a water inlet conduit or 
pipe 28 and hot water outlet pipe 30. Typically, hot water heater 21 also 
includes a set of legs 32 which elevate the tank from the floor 34, and 
often tank 21 will be positioned on a raised platform 34. 
While conduits 24, 26, 28 and 30 have some stabilizing effect on hot water 
heater 21, they are not designed for that purpose, and experience shows 
that they are not effective in preventing the hot water tank assembly from 
tipping over. Similarly, there are gas valve shut-off mechanisms which are 
sometimes installed on or proximate water heaters, but the mass of tank 
assembly 21 can break inlet conduit 24 upstream of the shut off valve, and 
a spark can ignite the escaping gas. Clearly, securement of the tank 
assembly against tipping adds very substantially to the overall safety of 
a hot water tank assembly in areas where moderate or major earthquakes are 
likely to occur. 
In order to secure tank 21 against tipping over, a bracket 41 is provided 
which has an arcuate surface 43 formed to substantially mate with and 
receive a significant portion of the periphery of tank 21. Arcuate surface 
43 cradles tank 21, providing security and stability; yet, the cradling 
capability is not so cumbersome as to impair removal or replacement of 
tank 21. Additionally, bracket 41 is formed with sides or edges 45 and 47, 
which are juxtaposed to sheetrock panels 23 and 25. 
Mounted to bracket 41 is a strap-like member 71, which is secured to and 
extends from mounting ear 73 to buckle or coupling assembly 75. The 
combination of bracket 41 and strap-like member or belt 71, therefore, 
provides a first means or bracket means extending substantially around, in 
this embodiment completely around, tank 21. As will be described further, 
moreover, the cradle surface 43 and flexible belt 71 secure the first 
means to tank 21 against any lateral or transverse movement with respect 
to the tank. 
One major reason that the use of plumber's strapping is ineffective to 
stabilize hot water heaters is that the motion of the tank can be in any 
direction transverse to the tank's longitudinal axis. (Vertical motion, of 
course, often accompanies the transverse motion.) This unpredictable 
motion will produce oscillation that can be effectively resisted in one 
direction (if the strapping is strong enough) but after results in a slack 
condition in the strapping in the opposite direction. The result of the 
strapping going slack is that significant displacement of the tank can 
occur in one direction which will be reinforced by the earthquake motion. 
The slack in the strapping, therefore, can allow momentum to build in the 
tank, with the result that the strapping or strapping fasteners will fail. 
In the present invention, therefore, one important feature of bracket 
assembly 22 is that it provides a slack-free positive coupling of the tank 
to a building structure which is not likely to fail during an earthquake, 
such as framing studs 27, 29, 31 and 33. In the present bracket assembly, 
the first or bracket means comprised of bracket 41 and belt 71 is secured 
in slack-free relation to the tank, preferably by cinching the belt down 
against the tank to seat the tank against cradle surface 43. 
In order to positively secure bracket 41 in substantially slack-free 
relation to the wall structure, second means or mounting means, preferably 
in the form of slidable mounting flanges 51 and 53, are mounted to bracket 
41. Any known method of adjustably mounting flanges 51 and 53 to bracket 
41 may be utilized as long as a substantially slack-free connection 
results. However, in the preferred form, a plurality of bolt receiving 
bracket holes 49 are spaced apart and extend along each of bracket edges 
45 and 47. 
FIG. 3, further, illustrates an enlarged, fragmentary, side elevation view 
of bracket mounting flange 51. As designed in accordance with the present 
invention, flanges 51 and 53 are U-shaped with at least one flange hole 37 
formed therein which will receive a bolt, such as bolts 55 and 57, 
therethrough so as to secure or lock the mounting flanges 51 and 53 to the 
edges 45 and 47 of bracket 41. Thus, referring to FIG. 2, mounting flanges 
51 on edge 45 can be slid along bracket edge 45 until they are aligned 
with framing studs 27 and 29. At that point, lag screws 61 and 63 can be 
screwed in through the wallboard and into the 2".times.4"'s. Depending on 
the size of framing studs 27 and 29, lag screws 61 and 63 may be of the 
same size, type and quality. Likewise, the mounting flanges 53 may be slid 
along edge 47 until they are aligned with studs 31 and 33. Mounting screws 
65 and 67 then can be screwed into studs 31 and 33, which are set 
typically, but not always, at about 16 inch centers. The adjustability of 
the mounting flanges is an important feature of the present invention 
since it facilitates retrofitting, and in many instances the studs in 
corner structures are irregularly spaced. Greater detail of the mounting 
flange assembly may be observed in FIG. 3. 
Furthermore, as is apparent in FIG. 2, and as illustrated in FIG. 3, 
flanges 51 and 53, themselves, preferably include a plurality of bolt 
receiving flange holes 37 which are spaced apart in a direction outwardly 
from the studs and extend through the U-shaped portion of flanges 51 and 
53. Thus, flanges 51 and 53 are not only slidable along edges 45 and 47, 
but edges 45 and 47 are also adjustable outwardly with respect to the 
distance from the framing studs and sheetrock panels 23 and 25. This 
feature facilitates retrofitting of bracket assembly 22 to existing hot 
water tank installations, and may well be required because of wall 
irregularities and the need to run plumbing between the bracket and wall. 
As will be apparent, bracket 41 also could be formed with a plurality of 
rows of openings 49, which are spaced apart in outwardly spaced relation, 
to permit various spacings from the building walls. As set forth above, 
bolts 55 and 57 secure mounting flanges 51 and 53 to edges 45 and 47, and 
lag screws 61, 63, 65 and 67 positively secure the adjustable mounting 
flanges to the framing studs. Holes 37 even may contain a lower threaded 
portion of the U-shaped section of flanges 51 and 53, as shown in FIG. 2. 
Bracket 41, therefore, can be customized further to the space or form 
provided. 
The hot water tank 21 can be secured against transverse displacement 
relative to mounting bracket 41 by several techniques. One would be 
comprised of use of a high-strength, wide fabric belt 71 of the type used, 
for example, in seat belt construction. Such material is amply flexible, 
yet, still provides the necessary strength and stability to secure a heavy 
cumbersome water tank under the stressful earthquake conditions. As shown 
in FIGS. 2 and 3, belt 71 can be secured bY a fastener 72 to a mounting 
ear or flange 73 at one end of the bracket and secured by a coupling 
buckle or housing 75 which releasably grips U-shaped buckle mount 77 
secured to bracket 41 proximate end 79 of the belt. The housing 75 
preferably includes a structure which will allow the belt end 79 to be 
cinched down so the belt 71 is secured tightly against the water tank. 
Such coupling devices are common in the field and provide easy coupling 
and de-coupling. Thus, arcuate surface 43, belt 71 and buckle 75 cooperate 
to extend tightly around the periphery of tank 21, thereby providing a 
stable, slack-free attachment of bracket 41 to tank 21. 
Another embodiment could include a metal strapping which is secured at both 
ends to bracket 41 with essentially no slack between the strapping and the 
tank. It is important that belt 71 hold the tank against the mating 
bracket surface 43 so that relative acceleration between the bracket, tank 
and belt will not occur. It is further noted that the adjustable tightness 
of the bracket-strap assembly to tank 21 is wholly independent of the 
positioning of flanges 51 and 53 along the bracket so as to be aligned 
with framing studs 27, 29, 31 or 33, or another building structure. This 
is unlike the conventional plumber's strapping systems in which the 
tightness of the strapping is dependent upon the attachment of the 
strapping ends to the adjacent wall. 
FIG. 4 illustrates further alternative embodiments of the same bracket 
assembly. Here, the hot water tank bracket assembly can principally be 
used to secure a hot water tank against a straight wall as opposed to a 
corner. Preferably that version of the mounting bracket will have a longer 
edge 45 which is juxtaposed to straight wall 23 and two, or even three, 
slidable mounting flanges that can be aligned with framing studs. As shown 
in FIG. 4, bracket 41 contains extended portions 81 and 83 which 
ultimately further extends wall facing edge 45. Flanges 51 are slidably 
aligned with framing studs 27, 29 and 31 and subsequently mounted to 
bracket 41 in a similar fashion as described above. This embodiment of 
bracket 41 also includes an arcuate surface 43, which substantially mates 
with a portion of the periphery of hot water tank 21, and strapping means 
71 draws the tank up against mating surface 43. As will be seen, surface 
43 need not continuously engage tank 21, and can include recessed areas 
44. 
In most installations, securement of the hot water tank by a bracket as 
above described positioned between about the middle of the tank and about 
one foot from the top of the tank will prevent the tank from tipping over. 
However, when the tank is placed on a pedestal, additional safety can be 
achieved by using a second bracket positioned approximately one foot from 
the bottom of the tank as well. 
Brackets 41 are shown in the drawing as being formed of a solid plastic 
material, but it will be understood that they also may be formed of a 
metal or even wood. If metal is used a sheet metal which is rolled formed 
to provide sufficient rigidity is desirable. Mounting flanges 51 and 53 
are shown as being U-shaped and extending over the top and bottom of 
bracket 41. It will be appreciated that L-shaped mounting flanges could be 
employed and that bracket 41 could be formed with U-shaped edges which 
receive a leg of the mounting flanges. Similarly, while fasteners 61, 63, 
65 and 67 are shown as lag screws, other means for positively securing the 
bracket-strap assembly to the building wall structure can be provided. 
Finally, it is also possible to have strap 71 extend completely around the 
tank and be slidably received by bracket 41. 
While in the foregoing specification this invention has been described in 
relation to certain preferred embodiments thereof, and many details have 
been set forth for purposes of illustration, it will be apparent to those 
skilled in the art that the invention is susceptible to additional 
embodiments and that certain of the details described herein can be varied 
considerably without departing from the basic principles of the invention. 
The hot water heater stabilizing bracket assembly of the present invention, 
therefore, provides a slackfree system for positively coupling a hot water 
tank to a building structural element which usually only fails under the 
most extreme of earthquake conditions. The present invention can be 
retrofit to a wide variety of installations to significantly reduce the 
fire hazard, which can cause as much damage as the damage produced by 
motion.