The present invention relates generally to water heaters, and more particularly to fill tubes for water heaters.
Hot water heaters of the tank type store water in the tank and heat the water to a set point temperature using electric heating elements or gas burners. Water with the highest temperature accumulates toward the top of the tank due to the differing density of water with temperature. As hot water is withdrawn from the top of the tank, the user will notice a reduction of water temperature during long periods of use. The industry metric that captures the ability of hot water tanks to deliver hot water is called the first-hour rating (FHR). The mixing of heated water within the tank with cold water being added to the tank decreases the temperature of the hot water already heated. During long periods of use, there comes a point when the heating elements, during the final stages of an FHR test, can no longer maintain the required set temperature. Because the tank is stratified by density, there is more hot water available towards the end of the test when there is no mixing at the inlet. Water during a drawn at a rate below what can be continuously heated to the cut-off temperature required by the FHR, results in a reduced FHR rating. Also, the mixing of heated water within the tank with cold water being added to the tank decreases the contact time of the heating elements with the coldest water, slowing replenishment of the hot water. The FHR of hot water tanks can be increased by reducing the mixing of the water within the tank.
A fill tube assembly for a water heater includes an elongated fill tube having an interior water flow axis and a tube wall with an inlet end and an outlet end, and an open interior communicating with a water inlet opening at the inlet end and with at least one fill tube water outlet opening in the tube wall for directing water radially outward from the fill tube. An elongated diffuser body at the outlet end of the fill tube seals with an outside surface of the tube wall at a sealing end closest to the inlet end of the fill tube, and has an open end at an end closest to the outlet end of the fill tube. The open end has a diameter larger than an outside diameter of the tube wall, thereby creating an diffuser water outlet opening between the diffuser body and the tube wall for redirecting radial water flow emanating from the fill tube water outlet opening toward the diffuser outlet opening.
The diffuser body can be conical. The fill tube can include a plurality of fill tube water outlet openings axially spaced apart at the outlet end of the fill tube. The fill tube water outlet openings can decrease in diameter toward the outlet end of the fill tube. The fill tube water outlet openings can have an axis between 10 and 80 degrees to the water flow axis of the fill tube. The fill tube water outlet openings can be oriented distally toward the outlet end of the fill tube and diffuser water outlet opening. The fill tube water outlet openings nearest the outlet end of the fill tube can be oriented between 90 and 170 degrees relative to the interior water flow axis of the fill tube. The distance travelled by water leaving the fill tube water outlet openings to reach the diffuser body can decrease with the distance from the outlet end of the fill tube.
The fill tube can include an antisiphon water outlet opening at the inlet end of the fill tube. The siphon water outlet opening has an axis, and the axis of the antisiphon opening can be between 100 and 170 degrees to the interior water flow axis of the fill tube.
The sealing end of the diffuser can include a detachable connection to the fill tube. The detachable connection can be an elastic band. The sealing end can include a fastener for affixing the sealing end to the fill tube.
The diffuser water outlet opening can be annular. The diffuser water outlet opening can be other shapes. The fill tube assembly can further include an attachment seam between the fill tube and the diffuser body. The attachment seam can be elongated and extending longitudinally down the fill tube.
The diameter of the diffuser water outlet opening can be 1.5 to 20 times larger than the diameter of the fill tube. The fill tube can have between 1 and 20 fill tube water outlet openings. The sum of the cross sectional areas of the water outlet openings can be larger than the cross sectional area of the open interior of the fill tube. The diffuser body can include shape memory high temperature silicone. Other materials are possible. The outlet end of the fill tube can be plugged.
A water heater can include a tank having a top, bottom and sides, with a tank water inlet and a tank water outlet. An elongated fill tube is connected to the tank water inlet and can have an interior water flow axis and a tube wall with an inlet end and an outlet end. An open interior communicates with a water inlet opening at the inlet end and at least one fill tube water outlet opening in the tube wall for directing water radially outward from the fill tube.
An elongated diffuser body is provided at the outlet end of the fill tube. The diffuser body seals with an outside surface of the tube wall at an end closest to the inlet end, and has an open end at an end closest to the outlet end of the fill tube. The open end has a diameter larger than an outside diameter of the tube wall, thereby creating an diffuser water outlet opening between the diffuser body and the tube wall for redirecting radial water flow emanating from the fill tube water outlet opening toward the diffuser water outlet opening. The longest distance from the diffuser water outlet opening to a bottom of the tank can be between π DD/4 and πDD/2, where DD is the diameter of the open end of the diffuser.
A method of heating water with a water heater can include the step of providing a water heater as described. Water is supplied to the water heater through the tank water inlet and the elongated fill tube, wherein water will emerge from the fill tube and be direct by the diffuser body to the diffuser water outlet opening. Heated water can be removed from the tank water outlet.
The diffuser body can be retrofitted to an existing fill tube by removing an existing water heater fill tube from the water heater, placing the diffuser onto the fill tube adjacent the outlet end, flexing the diffuser body to a contracted state, and placing the fill tube and the diffuser into the water heater tank. The fill tube with the diffuser body can be retrofitted to an existing water tank by removing an existing water heater fill tube from the water heater, providing a fill tube with a diffuser, flexing the diffuser body to a contracted state, and placing the fill tube and the diffuser into the water heater tank.
A diffuser for a water heater fill tube can have a tube wall with an outside diameter. The diffuser includes an elongated flexible diffuser body for positioning at the outlet end of the fill tube. The diffuser body can have a sealing end opening for mating and sealing with an outside surface of the tube wall at the sealing end closest to the inlet end of the fill tube, and can have an open end for positioning at an end closest to the outlet end of the fill tube. The open end can have a diameter larger than an outside diameter of the tube wall, thereby creating an diffuser water outlet opening between the diffuser body and the tube wall for redirecting radial water flow emanating from the fill tube water outlet opening toward the diffuser outlet opening.
The diffuser can further include weights at the open end for maintaining the diffuser open end in an open configuration. The diffuser can include a plurality of flexible ribs spaced apart on the flexible body, the ribs having an elasticity less than the elasticity of the diffuser body.
There are shown in the drawings embodiments that are presently preferred it being understood that the invention is not limited to the arrangements and instrumentalities shown, wherein:
A fill tube assembly for a water heater includes an elongated fill tube having a water flow axis and a tube wall with an inlet end and an outlet end. The fill tube has an open interior communicating with a water inlet opening at the inlet end and with at least one fill tube water outlet opening in the tube wall for directing water radially outward from the fill tube. A diffuser with an elongated diffuser body is provided at the outlet end of the fill tube. The diffuser body seals with an outside surface of the tube wall at a sealing end closest to the inlet end of the fill tube. The diffuser body has an open end at an end closest to the outlet end of the fill tube. The open end has a diameter larger than an outside diameter of the tube wall, thereby creating a diffuser water outlet opening between the diffuser body and the tube wall for redirecting radial water flow emanating from the fill tube water outlet openings toward the diffuser outlet opening. The outlet end of the fill tube can be plugged.
The diffuser body contains and redirects water flow from the fill tube water outlet openings into a larger enclosed space formed by the diffuser body. The flow area that should be provided by the diffuser water outlet opening for non-turbulent flow is a function of the interior flow diameter of the fill tube which can be denoted as DFT, and also the diameter of the diffuser water outlet opening which can be denoted as DD. The relationship between the DFT and DD for complete laminarization of flow depends on the length of the expanded section, as well as DD and DFT. For a round tube expanding to a cone shape, the length L required for complete laminar flow to be achieved is between 10-100 times the DFT. Similarly, for noncircular expanders the relationship is expanding the cross-section area gradually, but no simple correlation exists. It is known from the Bernoulli principle of fluid dynamics that as the flow area expands, the velocity of the flowing liquid will decrease. The Bernoulli energy balance requires that the velocity pressure of the liquid must decrease as the flow area increases, and the static pressure will increase. If the flow becomes turbulent, where the Reynolds number is greater than 2300 for round tubes, unwanted mixing will occur within the tank due to turbulent eddies. However, if the Reynolds number is reduced to below 2,300 due to an increase in the cross sectional area, then laminar flow will predominate. The length L required for complete laminar flow to be achieved is between 10-100 times the DFT for round tubes expanding to a cone shape. Thereby, fill tube water outlet openings that have a greater distance to the diffuser water outlet opening can have a higher flowrate, travel a longer distance in which laminarization can occur, and a larger diameter than those that are closer to the diffuser water outlet opening.
The cross sectional area of the diffuser water outlet opening should be larger the cross sectional area of the fill tube. The cross sectional area of the diffuser water outlet opening can be from 1.01-1000 times larger than the cross sectional area of the fill tube. The cross sectional area of the diffuser water outlet opening can be 1.01, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, or 100 times larger than the cross sectional area of the fill tube, or within a range of any high value and low value selected from these values.
The sum of the cross sectional areas of the fill tube water outlet openings should be larger than the cross sectional area of the open interior of the fill tube. The sum of the cross sectional areas of the fill tube water outlet openings should be 1.01, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 5.5, 6, 6.5, 7, 7.5, 8, 8.5, 9, 9.5, 10, 10.5, 11, 11.5, 12, 12.5, 13, 13.5, 14, 14.5, 15, 15.5, 16, 16.5, 17, 17.5, 18, 18.5, 19, 19.5, or 20 times larger than the cross sectional area of the open interior of the fill tube, or within a range of any high value and low value selected from these values.
The diffuser body can have any suitable shape to create expansion. The diffuser body can be conical. The conical shape offers an expanding cross sectional area in the direction of the diffuser water outlet opening, without corners and edges that could create turbulence. The distance travelled by water leaving the fill tube water outlet openings to reach the diffuser body decreases with the distance from the outlet end of the fill tube. Other shapes of gradual expansion of cross sectional area are possible.
The fill tube is generally elongated and positioned in the water tank so as to deliver water to a bottom portion of the tank such that only heated water is withdrawn from the water outlet of the water tank, which is usually at the top of the water heater tank. The fill tube has a plurality of fill tube water outlet openings axially spaced apart at the outlet end of the fill tube. The fill tube water outlet openings can decrease in diameter in the direction toward the outlet end of the fill tube. The size and number of the fill tube water outlet openings can vary.
The fill tube water outlet openings can be angled relative to the interior water flow axis of the fill tube. The fill tube water outlet openings can have an axis between 10 and 80 degrees to the long axis of the fill tube. This will direct the water outward toward the diffuser body, and also toward the diffuser water outlet opening. The angle of the fill tube water outlet openings relative to the water flow axis of the fill tube can be 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75 or 80 degrees, or can be within a range of any high value and low value selected from these values.
The fill tube water outlet openings located nearest the outlet end of the fill tube can be oriented differently than the fill tube water outlet openings further from the outlet end of the fill tube, and can be angled more toward the fill tube inlet. This will help to push out the diffuser body and hold the diffuser water outlet opening in an expanded condition. The distal water outlet openings between 90 and 170 degrees relative to the water flow axis of the fill tube, and towards the inlet end of the fill tube. The fill tube water outlet openings nearest the outlet end of the fill tube can oriented relative to the axis of the fill tube 90, 95, 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165, or 170 degrees, or within a range of any high value and low value selected from these values.
The fill tube can include an antisiphon water outlet opening at the inlet end of the fill tube. The antisiphon water outlet opening has an axis relative to the water flow axis of the fill tube between 100 and 170 degrees, such that water leaving the antisiphon opening is directed more toward the inlet end of the fill tube. The angle of the axis of the antisiphon water flow outlet opening to the interior water flow axis of the fill tube can be 100, 105, 110, 115, 120, 125, 130, 135, 140, 145, 150, 155, 160, 165, and 170 degrees, or within a range of any high value and low value selected from these values. Directing the axis of water flow from the antisiphon openings somewhat counter to the water flow axis of water flow through the fill tube will reduce the amount of water flowing from the antisiphon opening in the normal state of operation, reducing the mixing of cold water entering the tank through the fill tube with hot water at the top of the tank.
The diffuser body can be connected to the fill tube by any suitable means. The sealing end of the diffuser can have a detachable connection to the fill tube. The detachable connection is an elastic band. Other connecting structure, for example hose clamps, are possible. The sealing end can be secured to the fill tube with a fastener for affixing the sealing end to the fill tube. The diffuser is some instances be formed integrally with the fill tube, as by machining, welding, casting or molding.
The diffuser water outlet opening can take any suitable shape. The diffuser water outlet opening can be circular. The diffuser water outlet opening can be annular with the fill tube. There can be an attachment seam between the fill tube and the diffuser body, the attachment seam being elongated and extending longitudinally down the fill tube such that the flexible diffuser body will depend from the fill tube.
The diffuser body can be formed from different material or the same material as the fill tube. The diffuser body can be formed from a flexible material. The flexible material can be high temperature silicone. The diffuser body can be formed from a shape memory material such as a shape memory plastic.
A water heater according to the invention can include a tank having a top, bottom and sides, with a tank water inlet and a tank water outlet. An elongated fill tube is connected to the tank water inlet and has a long water flow axis, a tube wall, and an inlet end and an outlet end. An open interior communicates with a water inlet opening at the inlet end and at least one fill tube water outlet opening in the tube wall for directing water radially outward from the fill tube at the outlet end. A diffuser with an elongated diffuser body is provided at the outlet end of the fill tube. The diffuser body seals with an outside surface of the tube wall at an end closest to the inlet end, and has an open end at an end closest to the outlet end of the fill tube. The open end has a diameter larger than an outside diameter of the tube wall, thereby creating an diffuser water outlet opening between the diffuser body and the tube wall for redirecting radial water flow emanating from the fill tube water outlet opening toward the diffuser water outlet opening.
The positioning of the diffuser body relative to the bottom of the water tank can vary. In one embodiment, the longest distance from the diffuser water outlet opening to a bottom of the tank is between π DD/4 and π DD/2, where DD is the diameter of the open end of the diffuser.
A method of heating water with a water heater, includes the steps of providing a water heater according to the invention, supplying water to the water heater through the tank water inlet and an elongated fill tube assembly with a diffuser having an elongated diffuser body. Water will emerge from the fill tube and be directed by the diffuser body to a diffuser water outlet opening. The heated water can then be removed from the tank water outlet. In addition to this, hot water could enter through the outlet and cold water drawn from the long diffuser tube in a recirculation loop where an external heat source is heating the water. This is when no hot water is needed by the user and the tank is recovering to a hot state. This would be a method that would reduce the mixing in the tank during recharge. Furthermore, a short expanding dip tube (<9 inches long) may be used at the top of the tank at another inlet point, for the hot water to reduce mixing also.
The diffuser body can be retrofitted to an existing fill tube by removing an existing water heater fill tube from a water heater, placing the diffuser onto the fill tube adjacent the outlet end, such that an end of the diffuser body closest to the inlet end of the fill tube seals against the fill tube. The diffuser body is flexed or squeezed to a contracted state. The fill tube and the diffuser are positioned into the water heater tank and connected, whereupon the diffuser body will return to an expanded state. The fill tube with the diffuser body can be thereby retrofitted to an existing water tank by removing an existing water heater fill tube from the water heater, providing a fill tube with a flexible diffuser, flexing the diffuser body to a contracted state, and placing the fill tube and the diffuser into the water heater tank.
A diffuser for a water heater fill tube having a tube wall with an outside diameter, includes an elongated flexible diffuser body for positioning at the outlet end of the fill tube. The diffuser body has a sealing end for mating and sealing with an outside surface of the tube wall at the sealing end closest to the inlet end of the fill tube, and can have an open end for positioning at an end closest to the outlet end of the fill tube. The open end can have a diameter larger than an outside diameter of the tube wall, thereby creating an diffuser water outlet opening between the diffuser body and the tube wall for redirecting radial water flow emanating from the fill tube water outlet opening toward the diffuser outlet opening.
The diffuser can have additional structure to insure that the diffuser retains an appropriate shape in the water tank. The diffuser can include weights at the open end for maintaining the diffuser open end in an open configuration. The diffuser can include a plurality of flexible ribs circumferentially spaced apart on the flexible body and extending down the elongated diffuser body. The ribs having an elasticity less than the elasticity of the diffuser body, and act as a spring to open the diffuser body to an expanded state and to maintain the diffuser body in the expanded state, while permitting contraction of the diffuser body during installation. Other structure is possible.
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The flow from fill tube water outlet openings 50-62 is illustrated in
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In some current manufacturing methods of making water heaters, the water heater tank is first internally coated with an anticorrosion coating and baked at high temperature prior to completion of the tank. The invention can be used in such water heater tanks and manufacturing methods, and one embodiment is shown in
The water heater 200 includes a tank wall 202 and a top 204 and open bottom 208. It is through the open bottom 208 that the anticorrosion coating is applied to the interior of the tank 202. A fill tube opening 212 is provided in the top 204 for connecting a fill tube and the water inlet to the tank 200.
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Some water heaters have water inlet at the side of the tank and not at the top. A fill tube assembly 300 for such water tanks is shown in
This embodiment of the invention is shown in an electric heat pump water heater 350 in
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A fill tube assembly 440 according to the invention includes a fill tube 448, diffuser 444, a water inlet end 452 and antisiphon opening 456. The fill tube assembly 420 is placed through the opening 432 as shown in
The invention as shown in the drawings and described in detail herein disclose arrangements of elements of particular construction and configuration for illustrating preferred embodiments of structure and method of operation of the present invention. It is to be understood however, that elements of different construction and configuration and other arrangements thereof, other than those illustrated and described may be employed in accordance with the spirit of the invention, and such changes, alternations and modifications as would occur to those skilled in the art are considered to be within the scope of this invention as broadly defined in the appended claims. In addition, it is to be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting.
This application claims priority to U.S. Provisional Patent Application No. 63/107,651 filed on Oct. 30, 2020, entitled “HYDRAULICALLY OPENED CONE VERTICAL TUBE DIFFUSER WITH SLANTED ANTI-SIPHON HOLE”, the entire disclosure of which incorporated herein by reference.
This invention was made with government support under Contract No. DE-AC05-00OR22725 awarded by the U.S. Department of Energy. The government has certain rights in this invention.
Number | Date | Country | |
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63107651 | Oct 2020 | US |