Bathing installations typically include a heater assembly connected in a recirculating water flow path, with a pump to circulate water through the heater and typically a filter. The heater assembly may include an electrically powered heater element, such as a resistive wire embedded within a heater rod immersed within a heater chamber. With the heater element exposed to the water flow, heater failures due to corrosion can occur.
Exemplary bathing systems with heaters and electronic controllers are disclosed in U.S. Pat. Nos. 6,282,370 and 7,030,343, the entire contents of which are incorporated herein by this reference.
Features and advantages of the disclosure will readily be appreciated by persons skilled in the art from the following detailed description when read in conjunction with the drawing wherein:
In the following detailed description and in the several figures of the drawing, like elements are identified with like reference numerals. The figures are not to scale, and relative feature sizes may be exaggerated for illustrative purposes.
Exemplary embodiments of a heater assembly may provide improved reliability over previously used heaters in the bathing installation field. A resistive heater element is mounted in a heater chamber within a housing structure, which may be fabricated of a plastic material, and its terminal ends passed through openings formed in the housing structure and sealed in place by use of seal members. In an exemplary embodiment, the heater element is fabricated without any brazed or welded bulkhead members. This eliminates a source of corrosion. The heater element may include a coil portion with a relatively low watt density characteristic, as compared to traditional, shorter, heating elements of the same power rating. In this regard, the watt density characteristic may be defined as the power (watts) divided by the effective heater element surface area (square inches). The ability to utilize a longer element section with the same power consumption translates into cooler operational temperatures and less stress on the heater element. Terminal ends of the heater element are passed through ports formed in the housing structure, and the pass through connection is sealed from a non-wetted side of the housing structure. Current collectors are also free of any brazed or welded bulkhead members, and terminal ends are passed through ports formed in the housing structure and sealed from a non-wetted side of the housing structure. Temperature sensors are mounted in ports in the housing assembly, in thermal communication with a heater chamber within the housing structure. In other embodiments, the heater housing structure may be fabricated from metal, or a combination of metal and plastic material.
Referring now to
The cover plate 70 is configured for attachment to the peripheral flange portion of the housing and has a wetted surface 70A facing the trough region and a non-wetted surface 70B on an opposed side of the plate. The plate can be attached to the peripheral flange portion by threaded fasteners 72 received in threaded receptacles 63 in the flange portion of the housing. An o-ring seal 68 (
In an exemplary embodiment, the housing 60 and cover plate 70 are fabricated, e.g., by injection molding, from a thermoplastic material selected to resist the high temperatures created by operation of the heater, and impervious to the water flowing through the heater assembly. One exemplary plastic suitable for a bathing installation application is polyphenolsulfide (PPS), one example of which is marketed as Ryton® polyphenylene sulfide (PPS) by Chevron Phillips Chemical Company. For other applications, the housing and/or cover plate may be fabricated of metal. The o-ring 68 may be fabricated of an elastomeric material, such as silicone rubber.
In an exemplary embodiment, a resistive heating element 80 is disposed within the heating chamber of the housing assembly, and includes an elongated coil portion 80A and opposed terminal end portions 82A and 82B. The heating element position within the heating chamber is fixed by a lower spring clip or bracket 84A and an upper spring clip or bracket 84B. The bracket 84A spaces the coil portion 80A from the bottom of the trough portion of the housing 70, and the upper bracket 84B provides a resilient spring force pressing the coil portion down and into contact with the bracket 84A when the cover plate is attached to the housing in an assembled condition. In an exemplary embodiment, the heating element may be rated at 4000 watts, have an axial length of about ten inches, a coil diameter of about 2 inches, and 12 coil turns. The heater element in an exemplary embodiment includes a resistive wire potted with a heat resistance dielectric potting compound, within an outer shield. The terminal end portions of the heater element are configured for connection to line voltage to drive the heater. The terminal ends may be threaded, for direct mechanical and electrical attachment to conductive pads on a controller circuit board 200 (
The use of a coil heater element provides greater heater element length for a given heater enclosure length. The coil heater element can be provided in different wattages, with different watt densities, to accommodate different application requirements. For example, a 5500 watt heater with a coil heater element may be provided with a watt density of 90.96 watts/sq. in. and a 1500 watt heater may be provided with a watt density of 20.71 watts/sq. in. In comparison, a commercially available 5500 watt heater with a conventional loop heater element has a watt density of 164.97 watts/sq. in. and a 1500 watt heater with a loop heater element has a watt density of 44.99 watts/sq. in. These higher watt densities are quite typical for the industry, though not universal. In other embodiment, the heater assembly may employ a loop-type heater element.
The terminal end portions of the heating element 80 are passed through respective openings or ports 74A and 74B formed in the cover plate 70 at opposite ends thereof, and on opposite sides of the longitudinal center line of the cover plate.
The position of the heating element within the housing structure is fixed primarily by the spring clips 84A, 84B, which space the coil portion from the housing structure and the cover plate, so that the coil portion does not physically contact the housing structure. Brackets 85A, 85B may be crimped onto the heating element near the terminal ends to register the position of the terminal ends relative to the wetted surface of the plate 70. The brackets may be omitted for some embodiments. The brackets 85A and 85B may be made from stainless steel or other corrosion-resistant metal, such as the heater element sheath material, typically Incoloy® or titanium. There is some compressive force exerted on the terminal ends of the heating element by the o-rings and tube nuts as well. With the secure positioning of the heater element to reduce or eliminate vibration or rattles, the heater assembly can be used in high water flow rate applications, e.g. 250 gallons per minute or higher for some applications, as well as in lower flow rate applications.
In an exemplary embodiment, the heater assembly 50 may be provided with temperature sensors 102, 104 respectively positioned adjacent the heater ports 64A, 64B. The sensors are fitted into respective cover ports 76A, 76B, each of which includes a threaded boss.
For the exemplary embodiment in which the heater housing is a plastic, electrically non-conductive structure, providing a stray current collector function is a issue. The stray currents may exist due to a failure in the heater element, for example, and may pass through conductive paths including the bathing installation water. A robust stray current collection capability is provided by current collector structures 90 and 92, illustrated in detail in
In an exemplary embodiment, the heater ports 64A and 64B have generally tubular or cylindrical interior configurations, opening into the heater cavity 62.
The grounding bar 96 includes pressure connectors 96A, 96B at each end to receive the exposed ends of the current collector terminal portions, and make electrical connection to the current collectors. In an exemplary embodiment, the grounding bar 96 is connected to a bond lug of terminal block 232 on the outside of the plastic enclosure 230 via a solid copper wire 97 (
In an exemplary embodiment, the current collector system does not have any wetted connections that would be subject to corrosion. This provides enhanced reliability of the heater system.
A further advantage of the heater system is that the heater system can be installed in a water flow path in either direction. Thus, port 64A can be on the inlet side, or on the outlet side, providing flexibility to the bathing installation designer. The flexibility is a result of the use of temperature sensors adjacent each port, the current collectors at each port, and the secure positioning of the heater element within the heater chamber, reducing or eliminating vibration of the heater element due to the volume of water pumped through the heater.
Exemplary embodiments of the heater system may be disassembled and serviced in the field. This provides a significant advantage over conventional systems which are sealed, e.g. by adhesive or potting material, and can only be replaced in the event of a malfunction.
In an exemplary embodiment, the cover plate 70 is mounted to the housing 60 by threaded fasteners 72 which are received in threaded receptacles in the flange region of the housing. A fluid seal between the housing and the cover plate is provided by an o-ring 68 (
Since the cover plate seals for the heater element terminal end portions, the current collector terminals and the temperature sensors are all secured by removable, threaded fasteners, these fasteners may be removed in the field, the fasteners 72 removed, and the cover plate removed from the housing. The heater element, temperature sensors and the current collectors may be removed if needed from the housing for service or replacement. The various seals can also be replaced as needed.
As noted above, the heater assembly 50 can be configured for use in an embodiment in which the bathing installation controller is co-located with the heater, as illustrated in
In an embodiment configured for location remote from the controller, the top housing can be reduced in height, since the circuit boards would not be needed. Line voltage wiring can be directed connected to the heater element terminal ends, or to a line voltage connector block.
The tailpiece adapter 94B (FIGS. 1 and 13A-13D)) can be employed to connect the heater assembly 50 to a threaded fitting, e.g. on another device in the bathing installation recirculating flow path, and perform a male thread to female thread conversion. For example, the tailpiece adapter 94B may be employed to directly connect to a pump such as a circulation pump 250, as illustrated in
The tailpiece adapter 94B is shown in detail in
The tailpiece adapter set 94A may be connected directly to a rigid pipe or a pipe fitting by adhesive connection, for example. The tailpiece adapter set 94A is illustrated in
The fitting 272 includes a cover plate surface 272A for covering a portion of the port opening 64B, for example, with a tubular barbed port portion 272B extending from the surface about opening 272C. The fitting performs a size reducing function in this embodiment, say from a 2 inch port opening size for the port, to a one inch diameter tube size. This fitting may be used to connect the heater to a flexible tubing, for example, to a 1 inch diameter tube size. An o-ring groove 272E accepts a o-ring seal. The fitting 272 may be connected to the port opening by a nut 94-1.
The fitting 272 further includes registration tabs 272D, which are spaced to enter the slots formed in the ports, e.g. slots 64A-2 (
Although the foregoing has been a description and illustration of specific embodiments of the subject matter, various modifications and changes thereto can be made by persons skilled in the art without departing from the scope and spirit of the invention as defined by the following claims.
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Number | Date | Country | |
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20110019983 A1 | Jan 2011 | US |