The present invention relates to a water heater including a solar heating system with back-up electric heating.
This invention relates to a water heater for residential or commercial use having a primary heat source and a back-up heat source. In operation, the primary heat source heats a recirculating fluid medium which transfers heat to water in a storage tank. The primary heat source may operate by solar power, for example. The back-up heat source is an electric element that heats the water within the storage tank when the primary heat source is insufficient. The primary and back-up systems may be reversed depending upon the availability of either heat source.
Water heaters having primary and back-up heat sources are known, such as those disclosed in U.S. Pat. Nos. 4,037,785, 4,545,365, 4,615,328, 5,660,165 and 6,142,216, which are all incorporated herein by reference in their entirety. While water heaters having primary and back-up heat sources are known, manufacturers continually strive to improve their efficiency, reliability and/or thermal performance.
In one exemplary embodiment, a water heater is provided. The water heater includes a water storage tank, an upper heating element positioned within a top end portion of the water storage tank for heating water within the top end portion of the water storage tank and a lower heating element positioned within a bottom end portion of the water storage tank for heating water within the bottom end portion of the water storage tank. A thermostat including a temperature sensor is positioned at an elevation above the lower heating element for sensing a temperature of water within the water storage tank. The thermostat is configured to selectively activate the lower heating element as a function of the water temperature sensed by the temperature sensor of the thermostat. A tank heat exchanger is positioned within the bottom end portion of the water storage tank. The tank heat exchanger is configured to contain a fluid medium for heat exchange with water in the bottom end portion of the water storage tank.
In another exemplary embodiment, the water heater comprises a second temperature sensor positioned on the water storage tank at an elevation at or below the tank heat exchanger for measuring a temperature of the water within the water storage tank. A control system is configured to compare the temperature sensed by the second temperature sensor with a temperature of the fluid medium contained within the solar heat exchanger.
In yet another exemplary embodiment, a system for heating water is provided. The system comprises the water heater and a solar heat exchanger. The solar heat exchanger is fluidly coupled to the tank heat exchanger of the water heater for circulating a fluid medium through the tank heat exchanger.
The invention is best understood from the following detailed description when read in connection with the accompanying drawings. It is emphasized that, according to common practice, the various features of the drawings are not to scale. On the contrary, the dimensions of the various features are arbitrarily expanded or reduced for clarity. Included in the drawings are the following figures:
Exemplary features of selected embodiments of this invention will now be described with reference to the figures. It will be appreciated that the spirit and scope of the invention is not limited to the embodiments selected for illustration. Also, it should be noted that the drawings are not rendered to any particular scale or proportion. It is contemplated that any of the exemplary configurations and materials and sizes described hereafter can be modified within the scope of this invention.
Referring generally to the figures and according to one exemplary embodiment of the invention, a water heater 15 is provided. The water heater 15 includes a water storage tank 22, an upper heating element 32 positioned within a top end portion of the water storage tank 22 for heating water within the top end portion of the water storage tank 22 and a lower heating element 30 positioned within a bottom end portion of the water storage tank 22 for heating water within the bottom end portion off the water storage tank 22. A thermostat 31 including a temperature sensor 31′ is positioned at an elevation above the lower heating element 30 for sensing a temperature of water within the water storage tank 22. The thermostat 31 is configured to selectively activate the lower heating element 30 as a function of the water temperature sensed by the temperature sensor 31′ of the thermostat. A tank heat: exchanger 13 is positioned within the bottom end portion of the water storage tank 22. The tank heat exchanger 13 is configured to contain a fluid medium for heat exchange with water in the bottom end portion of the water storage tank 22.
In another exemplary embodiment, the water heater 15 comprises a second temperature sensor 44 positioned on the water storage tank 22 at an elevation at or below the tank heat exchanger 13 for measuring a temperature of the water within the water storage tank 22. A control system 60 is configured to compare the temperature sensed by the second temperature sensor 44 with a temperature of the fluid medium contained within the solar collector 18.
In yet another exemplary embodiment, a system 10 for heating water is provided. The system comprises the water heater 15 and a solar heat exchanger 18. The solar collector 18 is fluidly coupled to the tank heat exchanger 13 of the water heater 15 for circulating a fluid medium through the tank heat exchanger 13.
Referring now to
The solar-powered heating system 11 generally includes a heat exchanger 13 positioned within a lower interior region of the water tank 22 that is fluidly coupled to a solar collector 18 positioned for exposure to sunlight. When sufficient solar energy is available, the fluid medium is circulated through the solar collector 18 where it is heated by sunlight. The heated fluid medium and is then distributed through the heat exchanger 13 for heating water contained within the water tank 22.
Referring now to
The water heater 15 includes a cold water inlet port 20 at its top end. An inlet diptube 27 is coupled to the cold water inlet port 20 and extends to the bottom end of the water tank 22. As shown in
A hot water outlet port 21 is also provided at the top end of the water heater 15. An outlet device 29 is coupled to the hot water outlet port 21 and extends to the top end of the water tank 22. By way of non-limiting example, the outlet device 29 may extend into the interior of the water tank by 1-inch, for example, as measured from the top end of the water tank 22. A hot water supply line 14 is attached (either directly or indirectly) to the hot water outlet port 21 to deliver hot water from the water tank 22 to one or more hot water distribution devices (not shown), such as a shower, a faucet, a clothes washer, or a dishwasher, for example.
A water tempering device 16 is optionally provided for improving the hot water supply performance of the water heater 15. The water tempering device 16 is generally configured to divert a portion of the cold water from the cold water supply line 12 to the hot water supply line 14 to deliver tempered water to the point(s) of use. The water tempering device 16 includes provisions for coupling to the cold water inlet port 20 of the water heater 15, the hot water outlet port 21 of the water heater 15, the hot water supply line 14, and the cold water supply line 12. The water tempering device 16 generally comprises a bypass conduit 26 for diverting a portion of the cold water from the cold water supply line 12 and a mixing device 28 that is configured to selectively mix the cold water with the hot water from the hot water outlet port 21. The tempered water is ultimately delivered from the mixing device 28 into the hot water supply line 14. A thermostatically controlled valve (not shown) is housed within the mixing device 28 and is configured to control the flow of fluid through the bypass conduit 26 as a function of the temperature setting of the thermostatically controlled valve. Further details of water tempering devices are described in U.S. patent application Ser. No. 11/904,107 to Gordon et al., which is incorporated by reference herein in its entirety.
A sacrificial anode 37 is coupled to the top of the water tank 22 to extend into the water tank 22. The sacrificial anode 37 is configured to limit or prevent corrosion of the metallic components within the water tank 22. Although not shown, another sacrificial anode may also be coupled to one end of the outlet device 29 to further enhance corrosion protection.
As best shown in
Operation of the upper electrical heating element 32 is controlled by a thermostat 33, which includes an internal temperature sensor 33′. The temperature sensor 33′ may be mounted to the exterior surface of the tank 22 for sensing the water temperature through the tank wall. The thermistor 33′ is optionally positioned at an elevation above the upper heating element 32 to sense the temperature of the water directly above the upper heating element 32. At a predetermined minimum temperature of the water adjacent the temperature sensor 33′, the thermostat 33 energizes the upper electrical heating element 32 to heat the water in the top end (or the central portion) of the water tank. The temperature sensor 33′ may be generally referred to herein as a thermistor, and, thus, is not limited to being provided in the form of a temperature sensor.
Because the outlet device 29 draws water from the top end of the water tank 22, as shown in
As shown in
The lower electrical heating element 30 is positioned through an aperture 43 (see
As shown in
According to the exemplary embodiment shown in
Referring still to
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Referring still to
Referring now to
General operation of the solar-powered heating system 11 is described hereinafter. In operation, a fluid medium is distributed through the solar collector 18 where, in the presence of sunlight, the fluid medium absorbs solar energy and increases in temperature. The fluid medium may comprise a water and glycol mixture, propylene glycol antifreeze, or any other fluid or refrigerant known in the art. The heated fluid medium is then delivered through conduit 38 and into the heat exchanger 13. The heated fluid medium heats the water within the bottom of the water tank 22. The fluid medium is then recirculated back to the solar collector 18 through the conduit 40 for reheating.
With reference now to the individual components of the solar-powered heating system 11, the heat exchanger 13 is positioned within the lower interior region of the water tank 22 and fluidly coupled to the solar collector 18. The heat exchanger 13 generally comprises a coiled tube defining an inlet end 34 for receiving the fluid medium and an outlet end 36 for distributing the fluid medium. The coils of the heat exchanger 13 are composed of a thermally conductive material, such as copper or glass lined steel, for example, to facilitate heat exchange between the water within the water tank 22 and the fluid medium carried within the coiled portion of the heat exchanger 13.
Referring now to
Two coil spacing brackets 48 are optionally mounted to the coils of the heat exchanger 13. Each coil spacing bracket 48 is optionally welded to each individual coil to maintain spacing between adjacent coils of the heat exchanger 13 in an effort to reduce or eliminate noise caused by coil vibration. The coil spacing brackets 48 maximize the heat transfer surface area of each coil by preventing contact between adjacent coils. Another benefit of coil spacing brackets 48 is improved water circulation between adjacent coils, thereby decreasing stratification by permitting horizontal water flow during operation. The coil spacing brackets 48 may be mounted approximately 180 degrees apart to provide support for the heat exchanger 13 during shipping, handling and operation.
Unlike the heat exchanger disclosed in U.S. Pat. No. 5,660,165, the heat exchanger 13 embodiment shown in
According to another aspect of the invention, the heat exchanger 13 is positioned at an elevation below the thermostat 31 such that the thermostat 31 can sense the rising heat transferred into the water tank 22 by the heat exchanger 13.
According to yet another aspect of the invention, the thermostat 31 is positioned at an elevation corresponding to about two-thirds of the height of the water tank (measured from the top end of the water tank) and a heat exchanger is positioned beneath the thermostat 31. More particularly, when a user draws at least about two-thirds of the water from the water tank 22 (typical water draw for a hot shower, for example), the thermostat 31 is optimally positioned at the aforementioned elevation to sense and respond to that hot water demand.
According to still another aspect of the invention, the heat exchanger 13 and the lower heating element 30 are positioned at an elevation below the lower thermostat 31. More particularly, by positioning the thermostat at an elevation corresponding to about two-thirds of the height of the water tank, a limited amount of vertical clearance exists below the thermostat 31 to accommodate both the heat exchanger 13 and the lower heating element 30. The lower heating element 30 is positioned at an elevation below the lower thermostat 31 such that the thermostat 31 can sense the rising heat transferred into the water tank 22 by the lower heating element 30. Additionally, the heat exchanger 13 is positioned at an elevation below the lower thermostat 31 for the aforementioned reasons. For those reasons, the heat exchanger 13 is positioned at an elevation between the lower thermostat 31 and the lower heating element 30. Alternatively, the lower heating element 30 may be positioned between the heat exchanger 13 and the lower thermostat 31.
Referring now to the solar collector 18 of the solar powered heating system 11, the solar collector 18 is a device configured to absorb incident solar radiation, convert the solar radiation to thermal energy, and to transfer the thermal energy to a fluid medium distributed through the body of the solar collector. Solar collectors are generally known in the art and described in greater detail in U.S. Pat. No. 5,794,611 to Bottum, which is incorporated herein by reference in its entirety. The solar collector 18 is optimally positioned outdoors for exposure to sunlight.
The solar collector 18 includes an inlet passage 39 for receiving the fluid medium, an internal passageway (not shown) that is exposed to the sunlight for heating the fluid medium and an outlet passage 41 for distributing the fluid medium from the solar collector 18. The inlet passage 39 is fluidly coupled to the conduit 40 and the outlet passage 41 is fluidly coupled to the conduit 38.
A thermistor 46 is positioned within the internal passageway of the solar collector 18 proximal to the outlet passage 41 of the solar collector 18. The thermistor 46 measures the temperature of the fluid medium prior to its delivery into the heat exchanger 13. The thermistor 46 may be generally referred to herein as a temperature sensor, and, thus, is not limited to being provided in the form of a thermistor. The purpose of the thermistor 46 will be explained in greater detail with reference to
Conduits 38 and 40 fluidly couple the heat exchanger 13 to the solar collector 18 forming a continuous loop. According to one aspect of the invention, the conduits 38 and 40 are composed of a thermally-insulative material to limit heat dissipation to the environment.
The pump 42 is coupled to the conduit 38 (or conduit 40) for circulating the fluid medium through the solar-powered heating system 11. The pump 42 may be any commercially available pump. The valve 62 is coupled to the conduit 38 (or conduit 40) for permitting or prohibiting the flow of the fluid medium through the solar-powered heating system 11. In a closed positioned, the valve 62 limits or prevents the circulation of the fluid medium through the solar-powered heating system 11 and in the open position the valve 62 permits the circulation of the fluid medium through the solar-powered heating system 11. The valve 62 is an optional feature of the solar-powered heating system 11 and may be omitted.
In operation of the solar powered heating system 11, the pump 42 is activated and the valve 62 in an open state. The pump 42 circulates the fluid medium through the inlet passage 39 of the solar collector 18. The fluid medium is then urged through the internal passageway of the solar collector 18 for solar heating. The heated fluid medium is ultimately expelled from the solar collector 18 through the outlet passage 41 and into the conduit 38. The conduit 38 delivers the heated fluid medium from the solar collector 18 to the heat exchanger 13. The fluid medium is expelled from the heat exchanger 13 through the conduit 40. The conduit 40 delivers the fluid medium back to the solar collector 18 for re-heating.
Thermal energy is transferred from the fluid medium to the water contained within the bottom end of the water tank 22 only when the water temperature at the bottom end of the water tank 22 is less than the temperature of the fluid medium within the solar collector 18. For that reason, the solar-powered heating system 11 is configured to operate only when heat transfer is possible, i.e., when the temperature of the water within the bottom end of the water tank 22 is less than the temperature of the fluid medium within the solar collector 18. Operation of the water heating system 10 is described in greater detail with reference to
The control system 60 is generally configured to maintain the temperature of the water within the water tank 22 at a substantially constant temperature to limit service disruptions to the end user. The control system 60 may maintain the water tank 22 at a substantially constant temperature by activating the solar-powered heating system 11, activating the upper heating element 32 and/or activating the lower heating element 30 depending upon the configuration of the entire water heating system 10. Those skilled in the art will understand that the control system 60 may be configured in a variety of different fashions to achieve a substantially constant water temperature and is not limited to any configuration described herein.
Any description of the operation of the water heating system 10 may also be supplemented by the solar water heating system operating guidelines published by the Solar Rating and Certification Corporation (SRCC). The SRCC OG-300 Solar Water Heating System Design and Installation Guidelines and the SRCC OG-100 Guidelines for Certifying Solar Collectors provide operating guidelines for operating solar water heating systems. SRCC OG-100 and SRCC OG-300 are incorporated by reference herein in their entirety.
As shown schematically in
More particularly, if the temperature reported by thermistor 46 exceeds the temperature reported by thermistor 44 by more than a pre-determined value, the control system 60 activates the pump 42 to circulate the fluid medium through the heat exchanger 13 and the solar collector 18. Under this condition the temperature of the fluid medium is great enough to raise the temperature of the water contained within the bottom end of the water tank 22.
Conversely, if the temperature reported by thermistor 46 does not exceed the temperature reported by thermistor 44 by more than the pre-determined value, the control system 60 deactivates the pump 42 and the fluid ceases to circulate through the heat exchanger 13 and the solar collector 18. The control system 60 is also operatively connected to the valve 62 to discontinue circulation of the fluid medium through the solar-powered heating system 11. The control system 60 will turn off the pump 42 so that heat transfer fluid will not circulate unless needed. Such a valve is preferable where continued recirculation of the fluid medium below the pre-determined minimum temperature would result in system heat loss. The valve 62 is also preferable for servicing the heater. A properly located check valve will eliminate thermal siphoning. This circumstance occurs when the solar collector 18 is not exposed to a sufficient level of sunlight to heat the fluid medium to a level above the temperature of the water contained within the bottom end of the water tank 22. Continuing to operate the solar-powered heating system 11 under those conditions might actually remove heat from the water within the water tank 22.
According to another aspect of the invention, the control system is connected to the lower thermostat 31 of the water heater 15 such that the control system 60 controls the lower thermostat 31. It is contemplated that the control system 60 may deactivate the lower thermostat 31 (i.e., deactivating the lower heating element 30) when the solar-powered heating system 11 is operating. The connection between the control system 60 and the lower thermostat 31 is depicted by a broken line in
According to yet another aspect of the invention, the control system 60 is optionally connected to the upper thermostat 33 of the water heater 15 such that the control system 60 also controls the upper thermostat 33. According to one exemplary use of the invention, the upper thermostat 33 may be energized while the solar-powered heating system 11 is operating.
According to still another aspect of the invention, both heating elements 30 and 32 may operate simultaneously to heat the water within the water tank 22. Thus, the water heater 15 can act as a standard dual heating element water heater when sufficient heat is required. According to one aspect of the invention, the upper heating element 32 has priority over the lower heating element 30, i.e., the upper heating element 32 will be activated prior to the lower heating element 30. This configuration serves two purposes. First, the water contained within the top portion of the water tank 22 will be heated prior to the water contained within the bottom portion of the water tank 22, since the water contained within the top portion of the water tank 22 is the first to be delivered to the end user. The second purpose is to provide more time for the solar collector 18 to absorb solar energy and transfer that energy to the fluid medium. Activating the upper heating element 32 alone might not raise the temperature of the water within the bottom end of the water tank significantly.
Under normal operating conditions, the solar-powered heating system 11 is the sole and primary water heat source. However, when solar power generated by the solar collector 18 cannot sufficiently heat the recirculating fluid medium to a predetermined minimum temperature, the temperature sensors 31′ and 33′ sense the temperature drop and the thermostats 31 and 33 actuate one or both of the electrical heating elements 30 and 32, which act as a back-up heat source. Thereafter, the water heater 15 operates as a standard dual-element electric water heater, at least until the temperature sensed by temperature sensors 31′ and 33′ rises above the predetermined minimum temperature at which time one or both of the heating elements 30 and 32 are deactivated. Accordingly, solar-powered heating system 11 is the primary heat source and the electrical heating elements 30 and 32 are a back-up or auxiliary heat source.
It is contemplated that the back-up heating system can be reversed so that the electrical heating elements 30 and 32 can act as a primary heat sources with the solar-powered heating system 11 acting as a back-up or supplemental heat source. Such a back-up water heating system may be appropriate in climates where solar energy may be insufficient to provide continuous hot domestic water needs but may at times be sufficient to supplement the water heater heat source.
Although this invention has been described with reference to exemplary embodiments and variations thereof, it will be appreciated that additional variations and modifications can be made within the spirit and scope of this invention. Although this invention may be of particular benefit in the field of residential water heaters, it will be appreciated that this invention can be beneficially applied in connection with commercial or domestic water heaters and other heating systems as well.
This divisional application is related to and claims the benefit of co-pending U.S. patent application Ser. No. 12/189,943, filed on Aug. 12, 2008, which is incorporated herein by reference in its entirety for all purposes.
Number | Date | Country | |
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Parent | 12189943 | Aug 2008 | US |
Child | 13190791 | US |