초록 ▼

Control circuitry is disclosed for use with a tankless water heater system including a plurality of water conduits connected in series. The control circuitry includes a plurality of water heater elements, one each associated with each of the plurality of water conduits. A controller includes a centr

Control circuitry is disclosed for use with a tankless water heater system including a plurality of water conduits connected in series. The control circuitry includes a plurality of water heater elements, one each associated with each of the plurality of water conduits. A controller includes a central processing unit (CPU) with an operating program and each of the plurality of water heater elements are coupled to the CPU. The CPU is programmed to individually activate one of the water heater elements to a predetermined power level in response to a demand for heated water. The number of water heater elements activated and the power level of the activation is determined by the demand for heated water.

대표청구항 ▼

Having fully described the invention in such clear and concise terms as to enable those skilled in the art to understand and practice the same, the invention claimed is: 1. Control circuitry for a tankless water heater system, the tankless water heater system including a plurality of water conduits

Having fully described the invention in such clear and concise terms as to enable those skilled in the art to understand and practice the same, the invention claimed is: 1. Control circuitry for a tankless water heater system, the tankless water heater system including a plurality of water conduits connected in series, the series connection being further connectable to a cold water supply and to provide a heated water flow to a heated water demand site, the control circuitry comprising: a plurality of water heater elements, one each associated with each of the plurality of water conduits; a controller including a central processing unit with an operating program; a plurality of sensors positioned in the water flow and electrically coupled to the controller, at least one of the plurality of sensors providing an indication of the water temperature in an outlet of the series connection; connecting and operating circuitry coupling each of the plurality of water heater elements to the central processing unit; and the central processing unit being programmed to control the connecting and operating circuitry in accordance with indications from the plurality of sensors to individually and sequentially activate a first of the plurality of water heater elements in predetermined steps to a middle power level of the first water heater element less than a maximum power level of the first water heater element, activate a second of the plurality of water heater elements in predetermined steps to a middle power level of the second water heater element less than a maximum power level of the second water heater element, and activate the first water heater element from the middle power level of the first water heater element to the maximum power level of the first water heater element and then activate the second water heater element from the middle power level of the second water heater element to the maximum power level of the second water heater element in response to a demand for heated water, the number of the plurality of water heater elements sequentially activated and the sequential power level of the activation being determined by the demand for heated water. 2. Control circuitry as claimed in claim 1 wherein the operating program includes a predetermined schedule for activating additional ones of the plurality of water heater elements, in accordance with the sequential activation of the first and second water heater elements, as heat required for the demand for heated water increases. 3. Control circuitry as claimed in claim 2 wherein the operating program includes a predetermined schedule for activating additional ones of the plurality of water heater elements to additional power levels as heat required for the demand for heated water increases. 4. Control circuitry as claimed in claim 3 wherein, in accordance with the predetermined schedule, a first water heater element of the plurality of water heater elements is sequentially activated up to the middle power level of the first water heater element less than the maximum power level of the first water heater element for a first heat required, a second water heater element of the plurality of water heater elements is sequentially activated up to the middle power level of the second water heater element less than the maximum power level of the second water heater element for a second heat required higher than the first heat required, a third water heater element of the plurality of water heater elements is sequentially activated up to a middle power level of the third water heater element less than a maximum power level of the third water heater element for a third heat required higher than the second heat required, and a fourth water heater element of the plurality of water heater elements is sequentially activated up to a middle power level of the fourth water heater element less than a maximum power level of the fourth water heater element for a fourth heat required higher than the third heat required. 5. Control circuitry as claimed in claim 4 wherein the first water heater element is activated for the first heat required to a first power level, and for heat requirements greater than the first heat required and less than the second heat required the power level of the first water heater element is increased in predetermined increments. 6. Control circuitry as claimed in claim 5 wherein the second water heater element is activated for the second heat required to the first power level and for heat required greater than the second heat required and less than the third heat required the power level of the second water heater element is increased in predetermined increments. 7. Control circuitry as claimed in claim 6 wherein the third water heater element is activated for the third heat required to the first power level and for heat required greater than the third heat required and less than the fourth heat required the power level of the third water heater element is increased in predetermined increments. 8. Control circuitry as claimed in claim 7 wherein the fourth water heater element is activated for the fourth heat required to the first power level and for heat required greater than the fourth heat required and less than a maximum heat required the power level of the fourth water heater element is increased in predetermined increments. 9. Control circuitry as claimed in claim 8 wherein the first water heater element, the second water heater element, the third water heater element, and the fourth water heater element are cycled among the plurality of water heater elements by the controller. 10. Control circuitry as claimed in claim 8 wherein the first power level is approximately 12.50% of full power. 11. Control circuitry as claimed in claim 8 wherein the predetermined increments are approximately 12.50% of full power. 12. Control circuitry for a tankless water heater system, the tankless water heater system including a water heater module with four water conduits connected in series, the series connection being further connectable to a cold water supply and to provide a heated water flow to a heated water demand site, the control circuitry comprising: four water heater elements, one each associated with each of the plurality of water conduits; a controller including a central processing unit programmed with an operating program; a plurality of sensors positioned in the water flow and electrically coupled to the controller, at least one of the plurality of sensors providing an indication of the water temperature in an outlet of the series connection; connecting and operating circuitry coupling each of the plurality of water heater elements to the central processing unit; and the central processing unit being programmed to control the connecting and operating circuitry in accordance with indications from the plurality of sensors to individually activate a first water heater element to a first power level for a first heat required in response to a demand for heated water, and for heat required greater than the first heat required and less than a second heat required in response to a demand for heated water the central processing unit increases the power level of the first water heater element in predetermined increments up to a mid-power level less than a maximum power level of the first water heater element; the central processing unit being programmed to control the connecting and operating circuitry in accordance with indications from the plurality of sensors to individually activate a second water heater element of the four water heating elements to the first power level for the second heat required, and for heat required greater than the second heat required and less than a third heat required in response to a demand for heated water the central processing unit increases the power level of the second water heater element in predetermined increments up to a mid-power level less than a maximum power level of the second water heater element; the central processing unit being programmed to control the connecting and operating circuitry in accordance with indications from the plurality of sensors to individually activate a third water heater element of the four water heater elements to the first power level for the third heat required, and for heat required greater than the third heat required and less than a fourth heat required in response to a demand for heated water the central processing unit increases the power level of the third water heater element in predetermined increments up to a mid-power level less than a maximum power level of the third water heater element; and the central processing unit being programmed to control the connecting and operating circuitry in accordance with indications from the plurality of sensors to individually activate a fourth water heater element of the four water heater elements to the first power level for the fourth heat required, and for heat required greater than the fourth heat required and less than a fifth heat required in response to a demand for heated water the central processing unit increases the power level of the fourth water heater element in predetermined increments up to a mid-power level less than a maximum power level of the fourth water heater element. 13. Control circuitry as claimed in claim 12 wherein the first water heater element, the second water heater element, the third water heater element, and the fourth water heater element are cycled among the plurality of water heater elements by the controller. 14. Control circuitry as claimed in claim 12 wherein the first power level is approximately 12.50% of full power. 15. Control circuitry as claimed in claim 12 wherein the predetermined increments are approximately 12.50% of full power. 16. A method of controlling a tankless water heater system that includes a plurality of water conduits connected in series, the series connection being further connected to a cold water supply and to provide a heated water flow to a heated water demand site, the method comprising the steps of: providing a plurality of water heater elements, one each associated with each of the plurality of water conduits; providing a controller including a central processing unit programmed with an operating program, and coupling each of the plurality of water heater elements to the central processing unit, the operating program including the sequential steps of activating a first of the plurality of water heater elements in predetermined steps to a mid-power level of the first water heater element less than a maximum power level of the first water heater element, activating a second of the plurality of water heater elements in predetermined steps to a mid-power level of the second water heater element less than a maximum power level of the second water heater element, and activating the first water heater element from the mid-power level of the first water heater element to the maximum power level of the first water heater element and then activating the second water heater element from the mid-power level of the second water heater element to the maximum power level of the second water heater element; positioning a plurality of sensors in the water flow and electrically coupling the sensors to the controller, using at least one of the plurality of sensors as an indication of the water temperature in an outlet of the series connection; using the central processing unit individually activating the plurality of water heater elements to a predetermined power level, in accordance with the sequential steps of the operating program, in response to a demand for heated water, and using the operating program of the central processing unit determining the number of the plurality of water heater elements to activate and the power level of the activation by the demand for heated water. 17. A method as claimed in claim 16 wherein the step of providing the controller including the central processing unit programmed with the operating program includes programming a predetermined schedule for activating additional ones of the plurality of water heater elements as heat required for the demand for heated water increases. 18. A method as claimed in claim 16 wherein the step of providing the controller including the central processing unit programmed with the operating program includes programming a predetermined schedule for activating additional ones of the plurality of water heater elements to additional power levels as heat required for the demand for heated water increases. 19. A method as claimed in claim 18 wherein the operating program includes activating the first water heater element of the plurality of water heater elements for a first heat required, the second water heater element of the plurality of water heater elements for a second heat required higher than the first heat required, a third water heater element of the plurality of water heater elements for a third heat required higher than the second heat required, and a fourth water heater element of the plurality of water heater elements for a fourth heat required higher than the third heat required. 20. A method as claimed in claim 19 wherein the program includes activating the first water heater element for the first heat required to a first power level and for heat requirements greater than the first heat required and less than the second heat required increasing the power level of the first water heater element in predetermined increments. 21. A method as claimed in claim 20 wherein the program includes activating the second water heater element for the second heat required to the first power level and for heat required greater than the second heat required and less than the third heat required increasing the power level of the second water heater element in predetermined increments. 22. A method as claimed in claim 21 wherein the program includes activating the third water heater element for the third heat required to the first power level and for heat required greater than the third heat required and less than the fourth heat required increasing the power level of the third water heater element in predetermined increments. 23. A method as claimed in claim 22 wherein the program includes activating the fourth water heater element for the fourth heat required to the first power level and for heat required greater than the fourth heat required and less than a maximum heat required increasing the power level of the fourth water heater element in predetermined increments. 24. A method as claimed in claim 23 wherein the program cycles the activation of the first water heater element, the second water heater element, the third water heater element, and the fourth water heater element among the plurality of water heater elements.