IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0897644
(2001-06-29)
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발명자
/ 주소 |
- Pittman, Robert
- Cline, David J.
- Rosenau, Paul
- Clark, Timothy S.
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출원인 / 주소 |
|
인용정보 |
피인용 횟수 :
33 인용 특허 :
29 |
초록
▼
An improved water heater for use in spas, hot tubs, pools, hydrotherapy pools, bath tubs, and similar bodies of water used indoors, outdoors, or both indoors and outdoors are used for both therapeutic and recreational purposes. The water heater uses heating element technology know as thick film on s
An improved water heater for use in spas, hot tubs, pools, hydrotherapy pools, bath tubs, and similar bodies of water used indoors, outdoors, or both indoors and outdoors are used for both therapeutic and recreational purposes. The water heater uses heating element technology know as thick film on substrate comprising resistive elements bonded to the outer dry surface of a pipe to heat the pipe which in turn heats the water flowing therethrough. The heater is highly efficient due to the direct contact of the wet heating surface with the water and provides a smooth seamless inner heating surface by eliminating the need to pass electrical leads into the wet region of the heater. This virtually eliminates the risk of leaks in the water heater due to bulkhead fittings. The invention further eliminates the need for a heating element to be contained in the inner wet region of a spa heater, thereby reducing the risk of corrosion. The water heater is used in combination with an electronic controller having a microprocessor to control and regulate the operation of the water heater. The water heater can be used with electrical, electro-mechanical, and mechanical control systems for spas and can be retrofitted into existing spa applications.
대표청구항
▼
1. A water heater system for use in spas, hot tubs, pools, hydrotherapy pools, and bath tubs, the water heater system comprising:a water heater, the water heater comprising a heating chamber for heating water passing therethrough, the heating chamber comprising at least a portion of a recirculating
1. A water heater system for use in spas, hot tubs, pools, hydrotherapy pools, and bath tubs, the water heater system comprising:a water heater, the water heater comprising a heating chamber for heating water passing therethrough, the heating chamber comprising at least a portion of a recirculating water flow path and having an inlet, an outlet, and at least one heating surface, the heating surface having an inner wet surface and an outer dry surface, wherein a dielectric layer is coupled to the outer dry surface of the at least one heating surface by a binding material formed on the outer dry surface of the heating chamber, at least one resistor is attached to the dielectric layer, a conductive layer is connected to at least a portion of the at least one resistor, and at least one terminal is connected to at least a portion of the conductive layer; at least one temperature sensor located on or near the water heater for sensing a temperature indicative of a water temperature; an electronic controller having at least one microprocessor adapted to process signals from a plurality of devices providing water parameter information, wherein the electronic controller is connected to the at least one terminal and is arranged to control the operation of and to controllably energize the water heater, wherein the electronic controller is connected to the at least one temperature sensor, and wherein the electronic controller is configured for connection to a power supply and to control power to a pump for moving the water through the recirculating water flow path. 2. The water heater system according to claim 1, further comprising a high limit switch connected to the at least one temperature sensor and to the power supply for automatically causing the power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch requiring a manual reset once the water temperature has dropped below a predetermined temperature to allow power to be reconnected to the water heater.3. The water heater system according to claim 1, further comprising a high limit switch connected to the at least one temperature sensor and to the power supply for automatically causing the power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch automatically reconnecting the power supply once the water temperature has dropped below a predetermined temperature.4. The water heater system according to claim 1, wherein the at least one temperature sensor comprises:a first temperature sensor for sensing a first water temperature at a first location on or near the water heater and a second temperature sensor for sensing a second water temperature at a second location on or near the water heater; wherein the electronic controller receives temperature values before and after operating the water heater for a given time interval, and determines whether water is present as a result of the difference in the before and after temperature values, the electronic controller configured to turn off the water heater in the absence of water within the heating chamber, and to turn on the water heater upon subsequent receipt of water presence signals from the first and second temperature sensors indicating the presence of water within the heating chamber. 5. The water heater system according to claim 4, wherein the electronic controller deactivates operation of the water heater if a rate of rise of the first or second water temperature exceeds a specified value.6. The water heater system according to claim 4, further comprising a high limit switch connected to the first and second temperature sensors and to the power supply;wherein the high limit switch automatically causes power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch requiring a manual reset once the water temperature has dropped below a predetermined temperature. 7. The water heater system according to claim 4, further comprising a high limit switch connected to the first and second temperature sensors and to the power supply;wherein the high limit switch automatically causes power to be disconnected from the water heater when one of the first or second water temperatures exceeds a predetermined temperature, the high limit switch automatically reconnecting the power supply once the one of the first or second water temperature has dropped below a predetermined temperature. 8. The water heater system according to claim 1, further comprising a control panel connected to the electronic controller for inputting user preferences;wherein the electronic controller activates and deactivates the water heater in response to input signals from the at least one temperature sensor and the control panel. 9. The water heater system according to claim 1, wherein the at least one heating surface comprises three heating surfaces.10. The water heater system according to claim 1, wherein the at least one heating surface comprises three heating surfaces.11. The water heater system according to claim 1, wherein the at least one heating surface comprises four heating surfaces.12. The water heater system according to claim 1, wherein the at least one heating surface comprises a plurality of heating surfaces corresponding to the number of sides ‘n’ of a polygonal cross-section of the heating chamber.13. The water heater system according to claim 1, wherein the at least one heating surface comprises a plurality of heating surfaces corresponding to the number ‘n’ minus one (‘n?1’), wherein ‘n’ corresponds to the number of sides of a polygonal cross-section of the heating chamber.14. The water heater system according to claim 1, wherein the at least one heating surface is stainless steel and the binding material is a chromium oxide coating formed on the outer dry surface of the heating surface as a result of the stainless steel being heated to a certain temperature.15. The water heater system according to claim 1, wherein the at least one heating surface comprises a material selected from the group consisting of: copper, copper-nickel alloy, aluminum, aluminum alloys, magnesium, magnesium alloys, titanium, titanium alloys, steel, corrosion resistant varieties of steel, brass, ceramic, and glass.16. The water heater system according to claim 1, further comprising an inlet pipe and an outlet pipe at the heating chamber inlet and outlet.17. The water heater system according to claim 16, wherein the inlet pipe and outlet pipe have end-flanged couplings to facilitate connection with a water flow system.18. The water heater system according to claim 17, wherein the end-flanged couplings are made of PVC, plastic, or equivalent polymer material.19. The water heater system according to claim 1, further comprising an insulating overcoat covering the dielectric layer, the at least one resistor and the conductive layer.20. The water heater system according to claim 1, wherein the insulating overcoat comprises a glass insulating material.21. The water heater system according to claim 1, wherein the at least one resistor is an electric resistance layer which is a product of depositing an electrically conductive composition onto the binding material.22. The water heater system according to claim 1, wherein the at least one resistor is deposited in a pattern to provide one or more resistors.23. The water heater system according to claim 1, wherein the at least one resistor is deposited by electrostatic spraying with the use of a stencil.24. The water heater system according to claim 1, wherein the at least one resistor is screen-printed in a pattern to provide one or more resistors.25. The water heater system according to claim 1, wherein the dielectric layer, at least one resistor, and conductive layer comprise at least one screen-printed thick film power resistor bonded to the binding material.26. The water heater system according to claim 1, wherein the dimensions and layout of the dielectric layer, at least one resistor, and conductive layer depends on the size and the amount of heat necessary to heat a spa, hot tub, pool, hydrotherapy pool, bath tub, or similar body of water used indoors, outdoors, or both indoors and outdoors.27. The water heater system according to claim 1, wherein the at least one resistor comprises a plurality of resistors; the at least one terminal comprises a plurality of terminals; and wherein the plurality of resistors, the dielectric layer, the conductive layer, and the plurality of terminals are configured to provide variable operating resistance values.28. The water heater system according to claim 27, wherein the plurality of resistors, the dielectric layer, the conductive layer, and the plurality of terminals are configured to provide separate operating resistance values of 1.5 kilowatts and 4.0 kilowatts, and a combined operating resistance value of 5.5 kilowatts.29. The water heater system according to claim 1, wherein the at least one terminal is coupled to the conductive layer by multi-strand percussion welds.30. The water heater system according to claim 1, wherein the at least one terminal is coupled to the conductive layer by a stud welded onto the conductive layer.31. The water heater system according to claim 1, wherein the at least one temperature sensor is located within the heating chamber.32. The water heater system according to claim 16, wherein the at least one temperature sensor is located within the recirculating water flow path on or near the inlet or outlet pipe.33. The water heater system according to claim 1, wherein the at least one temperature sensor comprises two temperature sensor devices located at a first and second separated location on or within the heating chamber.34. The water heater system according to claim 1, wherein the at least one temperature sensor is a mechanical sensor such as a bulb and capillary device.35. The water heater system according to claim 1, further comprising a water presence sensor.36. The water heater system according to claim 1, further comprising a grounding connection coupled to the water heater.37. A water heater system for use in spas, hot tubs, pools, hydrotherapy pools, and bath tubs, the water heater system comprising:a recirculating water flow path, wherein water is recirculated from the body of water and one or more devices including a water heater for heating water passing therethrough, the water heater comprising a pipe, the pipe comprising at least a portion of the recirculating water flow path and having an outer surface an inner surface, an inlet and an outlet, wherein a dielectric layer is attached to at least a portion of the outer surface of the pipe by a binding material formed on the outer surface of the pipe and configured to bind the at least one dielectric layer to the outer surface of the pipe, at least one resistor is attached to the dielectric layer, a conductive layer is connected to at least a portion of the at least one resistor, and at least one terminal is connected to at least a portion of the conductive layer; at least one temperature sensor located on or near the pipe for sensing a temperature indicative of a water temperature; and an electronic controller having at least one microprocessor adapted to process signals from a plurality of devices providing water parameter information, wherein the electronic controller is connected to the the at least one temperature sensor and the at least one terminal and wherein the electronic controller is arranged to control the operation of the water heater and to controllably energize the water heater, and is configured for connection to a power supply and to control power to a pump for recirculating the water through the recirculating water flow path. 38. The water heater system according to claim 37, further comprising a high limit switch connected to the at least one temperature sensor and to the power supply for automatically causing the power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch requiring a manual reset once the water temperature has dropped below a predetermined temperature to allow power to be reconnected to the water heater.39. The water heater system according to claim 37, further comprising a high limit switch connected to the at least one temperature sensor and to the power supply for automatically causing the power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch automatically reconnecting the power supply once the water temperature has dropped below a predetermined temperature.40. The water heater system according to claim 37, wherein the at least one temperature sensor comprises:a first temperature sensor for sensing a first water temperature at a first location on or near the water heater, and a second temperature sensor for sensing a second water temperature at a second location on or near the water heater; wherein the electronic controller receives temperature values before and after operating the water heater for a given time interval, and determines whether water is present as a result of the difference in the before and after temperature values, the electronic controller configured to turn off the water heater in the absence of water within the pipe and turn on the water heater upon subsequent receipt of water presence signals from the first and second temperature sensors indicating the presence of water within the pipe. 41. The water heater system according to claim 40, wherein the electronic controller deactivates operation of the water heater if the water temperature has a rate of rise at the first or second location that exceeds a specified value.42. The water heater system according to claim 40, further comprising a high limit switch connected to the first and second temperature sensors and to the power supply;wherein the high limit switch automatically causes power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch requiring a manual reset once the water temperature has dropped below a predetermined temperature. 43. The water heater system according to claim 40, further comprising a high limit switch connected to the first and second temperature sensors and to the power supply; wherein the high limit switch automatically causes power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch automatically reconnecting the power supply once the water temperature has dropped below a predetermined temperature.44. The water heater system according to claim 37, further comprising a control panel connected to the electronic controller for inputting user preferences;wherein the electronic controller activates and deactivates the heater in response to input signals from the temperature sensors and the control panel. 45. The water heater system according to claim 37, wherein the pipe is stainless steel and the binding material is a chromium oxide coating formed on the outer surface of said pipe as a result of the stainless steel being heated to a certain temperature.46. The water heater system according to claim 37, wherein the pipe comprises a material selected from the group consisting of: copper, copper-nickel alloy, aluminum, aluminum alloys, magnesium, magnesium alloys, titanium, titanium alloys, steel, corrosion resistant varieties of steel, brass, ceramic, and glass.47. The water heater system according to claim 37, wherein the pipe is flanged at the inlet and outlet.48. The water heater system according to claim 37, further comprising couplings at the pipe inlet and pipe outlet to facilitate connection with a water flow system.49. The water heater system according to claim 48, wherein the couplings are made of PVC, plastic, or equivalent polymer material.50. The water heater system according to claim 37, wherein the pipe has an inner diameter of three inches or less.51. The water heater system according to claim 37, wherein the pipe has an inner diameter of one and three-quarters inches (1¾″).52. The water heater system according to claim 37, wherein the pipe has an inner diameter of two and one-quarter inches (2¼″).53. The water heater system according to claim 37, further comprising an insulating overcoat covering the dielectric layer, the at least one resistor and the conductive layer.54. The water heater system according to claim 53, wherein the insulating overcoat comprises a glass insulating material.55. The water heater system according to claim 37, wherein the at least one resistor is an electric resistance layer which is a product of depositing an electrically conductive composition onto the binding material.56. The water heater system according to claim 37, wherein the at least one resistor is deposited in a pattern to provide one or more resistors.57. The water heater system according to claim 37, wherein the at least one resistor is deposited onto the binding material by electrostatic spraying with the use of a stencil.58. The water heater system according to claim 37, wherein the at least one resistor is screen-printed in a pattern to provide one or more resistors.59. The water heater system according to claim 37, wherein the dielectric layer, at least one resistor, and conductive layer comprise at least one screen-printed thick film power resistor bonded to the binding material.60. The water heater system according to claim 37, wherein the dimensions and layout of the dielectric layer, at least one resistor, and conductive layer depends on the size and the amount of heat necessary to heat a spa, hot tub, pool, hydrotherapy pool, bath tub, or similar body of water used indoors, outdoors, or both indoors and outdoors.61. The water heater system according to claim 37, wherein the at least one resistor comprises a plurality of resistors; the at least one terminal comprises a plurality of terminals; and wherein the plurality of resistors, the dielectric layer, the conductive layer, and the plurality of terminals are configured to provide variable operating resistance values.62. The water heater system according to claim 61, wherein the plurality of resistors, the dielectric layer, the conductive layer, and the plurality of terminals are configured to provide separate operating resistance values of 1.5 kilowatts and 4.0 kilowatts, and a combined operating resistance value of 5.5 kilowatts.63. The water heater system according to claim 37, wherein the at least one terminal is coupled to the conductive layer by multi-strand percussion welds.64. The water heater system according to claim 37, wherein the at least one terminal is coupled to the conductive layer by a stud welded onto the conductive layer.65. The water heater system according to claim 37, wherein the at least one temperature sensor is located within the recirculating water flow path within or near the pipe.66. The water heater system according to claim 37, wherein the at least one temperature sensor comprises two temperature sensor devices located at a first and second separated location on or within the pipe.67. The water heater system according to claim 37, wherein the at least one temperature sensor is a mechanical sensor such as a bulb and capillary device.68. The water heater system according to claim 37, further comprising a water presence sensor.69. The water heater system according to claim 37, further comprising a grounding connection coupled to the water heater.70. The water heater system according to claim 69, wherein the grounding connection comprises a clamp coupled to the pipe and connected to a ground source.71. A water heater system for use in spas, hot tubs, pools, hydrotherapy pools, and bath tubs, the water heater system comprising:a recirculating water flow path, wherein water is recirculated from the body of water and one or more devices including a water heater for heating water passing therethrough, the water heater comprising a heating chamber comprising at least a portion of a recirculating water flow path and having an inlet, and outlet, and at least one heating surface, the heating surface having an inner wet surface and an outer dry surface, wherein a dielectric layer is coupled to the outer dry surface of the at least one heating surface by a binding material formed on the outer dry surface of the heating chamber, at least one resistor is attached to the dielectric layer, a conductive layer is connected to at least a portion of the at least one resistor, and at least one terminal is connected to at least a portion of the conductive layer; at least one temperature sensor located on or near the water heater for sensing a temperature indicative of a water temperature; at least one water presence sensor located on or near the heating chamber for sensing the presence or absence of water within the pipe; at least one electronic controller, wherein the at least one electronic controller is connected to the at least one temperature sensor and the at least one water presence sensor; and wherein the electronic controller is configured to connect to a power supply for controllably energizing the water heater to regulate the temperature of the water heater and configured to control power to a pump for recirculating the water through the recirculating water flow path; wherein the at least one electronic controller disconnects power to the water heater when the temperature sensed by the at least one temperature sensor exceeds a predetermined temperature and allows power to be reconnected to the water heater once the temperature has dropped below a predetermined temperature; wherein the at least one electronic controller disconnects power to the water heater when the at least one water presence sensor detects the absence of water within the pipe and allows power to be reconnected to the water heater once the at least one water presence sensor senses water present within the pipe. 72. The water heater system according to claim 71, wherein the at least one power controlling device requires a manual reset after power to the water heater has been disconnected.73. The water heater system according to claim 71, wherein the at least one power controlling device automatically reconnects power to the water heater after it has been disconnected.74. The water heater system according to claim 71, wherein the at least one power controlling device has a high limit switch connected to the at least one temperature sensor and to the power supply for automatically causing the power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch requiring a manual reset once the water temperature has dropped below a predetermined temperature to allow power to be reconnected to the water heater.75. The water heater system according to claim 71, wherein the at least one power controlling device has a high limit switch connected to the at least one temperature sensor and to the power supply for automatically causing the power to be disconnected from the water heater when the water temperature exceeds a predetermined temperature, the high limit switch automatically reconnecting the power supply once the water temperature has dropped below a predetermined temperature.76. The water heater system according to claim 71, wherein the heating chamber is stainless steel and the binding material is a chromium oxide coating formed on the outer surface of said heating chamber as a result of the stainless steel being heated to a certain temperature.77. The water heater system according to claim 71, wherein the heating chamber comprises a material selected from the group consisting of: copper, copper-nickel alloy, aluminum, aluminum alloys, magnesium, magnesium alloys, titanium, titanium alloys, steel, corrosion resistant varieties of steel, brass, ceramic, and glass.78. The water heater system according to claim 71, wherein the heating chamber is flanged at the inlet and outlet.79. The water heater system according to claim 71, further comprising couplings at the heating chamber inlet and heating chamber outlet to facilitate connection with a water flow system.80. The water heater system according to claim 79, wherein the couplings are made of PVC, plastic, or equivalent polymer material.81. The water heater system according to claim 71, wherein the heating chamber has an inner diameter of three inches or less.82. The water heater system according to claim 71, wherein the heating chamber has an inner diameter of one and three-quarters inches (1¾″).83. The water heater system according to claim 71, wherein the heating chamber has an inner diameter of two and one-quarter inches (2¼″).84. The water heater system according to claim 71, further comprising an insulating overcoat covering the dielectric layer, the at least one resistor and the conductive layer.85. The water heater system according to claim 84, wherein the insulating overcoat comprises a glass insulating material.86. The water heater system according to claim 71, wherein the at least one resistor is an electric resistance layer which is a product of depositing an electrically conductive composition onto the binding material.87. The water heater system according to claim 71, wherein the at least one resistor is deposited in a pattern to provide one or more resistors.88. The water heater system according to claim 71, wherein the at least one resistor is deposited by electrostatic spraying with the use of a stencil.89. The water heater system according to claim 71, wherein the at least one resistor is screen-printed in a pattern to provide one or more resistors.90. The water heater system according to claim 71, wherein the dielectric layer, at least one resistor, and conductive layer comprise at least one screen-printed thick film power resistor bonded to the binding material.91. The water heater system according to claim 71, wherein the dimensions and layout of the dielectric layer, at least one resistor, and conductive layer depends on the size and the amount of heat necessary to heat a spa, hot tub, pool, hydrotherapy pool, bath tub, or similar body of water used indoors, outdoors, or both indoors and outdoors.92. The water heater system according to claim 71, wherein the at least one resistor comprises a plurality of resistors; the at least one terminal comprises a plurality of terminals; and wherein the plurality of resistors, the dielectric layer, the conductive layer, and the conductive layer, and the plurality of terminals are configured to provide variable operating resistance values.93. The water heater system according to claim 92, wherein the plurality of resistors, the dielectric layer, the conductive layer, and the plurality of terminals are configured to provide separate operating resistance values of 1.5 kilowatts and 4.0 kilowatts, and a combined operating resistance value of 5.5 kilowatts.94. The water heater system according to claim 71, wherein the at least one terminal is coupled to the conductive layer by multi-strand percussion welds.95. The water heater system according to claim 71, wherein the at least one terminal is coupled to the conductive layer by a stud welded onto the conductive layer.96. The water heater system according to claim 71, wherein the at least one temperature sensor is located within the recirculating water flow path within or near the pipe.97. The water heater system according to claim 71, wherein the at least one temperature sensor comprises two temperature sensor devices located at a first and second separated location on or within the heating chamber.98. The water heater system according to claim 71, wherein the at least one temperature sensor is a mechanical sensor such as a bulb and capillary device.99. The water heater system according to claim 71, wherein the water presence sensor is a pressure switch.100. The water heater system according to claim 71, wherein the water presence sensor is a flow meter.101. The water heater system according to claim 71, wherein the water presence sensor is a vacuum switch.102. The water heater system according to claim 71, wherein the water presence sensor comprises a solid state sensing device.103. The water heater system according to claim 71, further comprising a grounding connection coupled to the water heater.104. The water heater system according to claim 103, wherein the grounding connection comprises a clamp coupled to the heating chamber and connected to a ground source.105. A water heater system for use in spas, hot tubs, pools, hydrotherapy pools, bath tubs, and similar bodies of water used indoors, outdoors, or both indoors and outdoors, the water heater system comprising:a water heater, the water heater comprising a heating chamber for heating water passing therethrough, the heating chamber comprising at least a portion of a recirculating water flow path and having an inlet, an outlet, and at least one heating surface, the heating surface having an inner wet surface and an outer dry surface, wherein the heating chamber comprises electrically non-conductive material and at least one resistor is attached directly to the outer dry surface of the heating chamber and a conductive layer is connected to at least a portion of the at least one resistor, and at least one terminal is connected to at least a portion of the conductive layer; at least one temperature sensor located on or near the water heater for sensing a temperature indicative of a water temperature; an electronic controller having at least one microprocessor adapted to process signals from a plurality of devices providing water parameter information, wherein the electronic controller is connected to the at least one terminal and is arranged to control the operation of and to controllably energize the water heater, wherein the electronic controller is connected to the at least one temperature sensor, and wherein the electronic controller is configured for connection to a power supply and to control power to a pump for recirculating the water through the recirculating water flow path. 106. The water heater system according to claim 105, wherein the at least one resistor comprises electrically conductive particles dispersed in a binding material.107. The water heater system according to claim 37, wherein the pipe comprises a cylindrical pipe.108. The water heater system according to claim 37, wherein the pipe is straight, unbent and cylindrical between the inlet and the outlet.109. A recirculating water heating system for use in spas, hot tubs, pools, hydrotherapy pools, and bath tubs, the recirculating water heating system comprising:a vessel for holding water; a recirculating pump for recirculating water from the vessel through a recirculating water flow path; a water heater, the water heater comprising a heating chamber for heating the water passing therethrough, the heating chamber comprising at least a portion of the recirculating water flow path and having an inlet, and outlet, and at least one heating surface, the heating surface having an inner wet surface and an outer dry surface, wherein a dielectric layer is coupled to the outer dry surface of the at least one heating surface by a binding material formed on the outer dry surface of the heating chamber, at least one resistor is attached to the dielectric layer, a conductive layer is connected to at least a portion of the at least one resistor, and at least one terminal is connected to at least a portion of the conductive layer; at least one temperature sensor located on or near the water heater for sensing a temperature indicative of a water temperature; an electronic controller having at least one microprocessor adapted to process signals from a plurality of devices providing water parameter information, wherein the electronic controller is connected to the at least one terminal and is arranged to control the operation of and to controllably energize the water heater, wherein the electronic controller is connected to the at least one temperature sensor, and wherein the electronic controller is configured for connection to a power supply and to control power to the recirculating pump for recirculating the water through the recirculating water flow path. 110. A spa system, comprising:a vessel for holding a body of water; a recirculating water flow path from the vessel and returning back to the vessel; a pump connected in the recirculating water flow path for recirculating water from the vessel through the recirculating water flow path; a heating chamber comprising at least a portion of the recirculating water flow path; a heating element coupled to an outer dry surface of the heating chamber, the heating element comprising a thick-film resistor applied over a dielectric layer attached to the outer dry surface of the heating chamber; and an electronic controller having at least one microprocessor adapted to process signals from a plurality of devices providing water parameter information. 111. The spa system according to claim 110, wherein the electronic controller is connected to a terminal for connecting the resistor to power, and wherein the electronic controller is arranged to controllably energize the water heater responsive to at least one of the plurality of devices.112. The spa system according to claim 111, wherein the plurality of devices comprises at least one temperature sensor and at least one water presence sensor.113. The spa system according to claim 111, wherein the plurality of devices comprises a first temperature sensor for sensing a first water temperature at a first location on or near the water heater and a second temperature sensor for sensing a second water temperature at a second location on or near the water heater;wherein the electronic controller receives temperature values before and after operating the water heater for a given time interval, and determines whether water is present as a result of the difference in the before and after temperature values, the electronic controller configured to turn off the water heater in the absence of water within the heating chamber, and to turn on the water heater upon subsequent receipt of water presence signals. 114. The spa system according to claim 111, wherein the plurality of devices comprises at least one temperature sensor and at least one water presence sensor;wherein the electronic controller disconnects power to the water heater when a temperature sensed by the at least one temperature sensor exceeds a predetermined temperature and allows power to be reconnected to the water heater once the temperature has dropped below a predetermined temperature; and wherein the electronic controller disconnects power to the water heater when the at least one water presence sensor detects the absence of water within the pipe and allows power to be reconnected to the water heater once the at least one water presence sensor senses water present within the pipe.
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