Powering wireless components in a heat trace system
First Claim
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1. A system comprising:
- a piping system comprising a plurality of vessels;
a main control system comprising an AC electrical power source;
a plurality of heat trace elements, wherein each of the plurality of heat trace elements is adjacent to at least one of the plurality of vessels of the piping system, and wherein each of the plurality of heat trace elements is connected to the AC electrical power source of the main control system to conduct AC current from the AC electrical power source; and
a plurality of wireless modules distributed throughout the piping system, wherein each wireless module;
is connected to and powered by an associated heat trace element of the plurality of heat trace elements;
comprises an AC-to-DC converter that converts AC voltage from the associated heat trace element to DC voltage;
comprises a switch connected to the AC-to-DC converter;
comprises a first controller for controlling the switch;
comprises a supercapacitor connected to the AC-to-DC converter via the switch, wherein the supercapacitor is for storing energy from the associated heat trace element coupled to the supercapacitor by the AC-to-DC converter and the switch, wherein the energy stored by the supercapacitor from the associated heat trace element is for powering the wireless module, and wherein the first controller controls the switch based on a voltage across the supercapacitor; and
comprises an RF module for communicating wirelessly with the main control system via a wireless communication network.
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Abstract
Heat trace system for heating vessels of a piping system comprises a main control system, a plurality of heat trace elements, and a plurality of wireless modules. Each heat trace element is adjacent to one of the vessels of the piping system and connected to an electrical power source of the main control system 16. Each of the wireless modules: (a) is connected to and powered by an associated heat trace element; (b) comprises an energy storage device connected to the associated heat trace element for storing energy from the associated heat trace element to power the wireless module; and (c) comprises an RF module for communicating wirelessly with the main control system via a wireless communication network. The stored energy in the energy storage device can be used to power components of the wireless module, even when no current is flowing in the heat trace element to which the wireless module is connected.
13 Citations
18 Claims
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1. A system comprising:
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a piping system comprising a plurality of vessels; a main control system comprising an AC electrical power source; a plurality of heat trace elements, wherein each of the plurality of heat trace elements is adjacent to at least one of the plurality of vessels of the piping system, and wherein each of the plurality of heat trace elements is connected to the AC electrical power source of the main control system to conduct AC current from the AC electrical power source; and a plurality of wireless modules distributed throughout the piping system, wherein each wireless module; is connected to and powered by an associated heat trace element of the plurality of heat trace elements; comprises an AC-to-DC converter that converts AC voltage from the associated heat trace element to DC voltage; comprises a switch connected to the AC-to-DC converter; comprises a first controller for controlling the switch; comprises a supercapacitor connected to the AC-to-DC converter via the switch, wherein the supercapacitor is for storing energy from the associated heat trace element coupled to the supercapacitor by the AC-to-DC converter and the switch, wherein the energy stored by the supercapacitor from the associated heat trace element is for powering the wireless module, and wherein the first controller controls the switch based on a voltage across the supercapacitor; and comprises an RF module for communicating wirelessly with the main control system via a wireless communication network. - View Dependent Claims (2, 3, 4, 5, 6, 7)
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8. A heat trace system for heating vessels in a piping system, the heat trace system comprising:
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a main control system comprising an AC electrical power source; a plurality of heat trace elements, wherein each of the plurality of heat trace elements is adjacent to at least one of the vessels of the piping system, and wherein each of the plurality of heat trace elements is connected to the AC electrical power source of the main control system to conduct AC current from the electrical power source; and a plurality of wireless modules distributed throughout the piping system, wherein each wireless module; is connected to and powered by an associated heat trace element of the plurality of heat trace elements; comprises an AC-to-DC converter that converts AC voltage from the associated heat trace element to DC voltage; comprises a switch connected to the AC-to-DC converter; comprises a first controller for controlling the switch; comprises a supercapacitor connected to the AC-to-DC converter via the switch, wherein the supercapacitor is for storing energy from the associated heat trace element coupled to the supercapacitor by the AC-to-DC converter and the switch, wherein the energy stored by the supercapacitor from the associated heat trace element is for powering the wireless module, and wherein the first controller controls the switch based on a voltage across the supercapacitor; and comprises an RF module for communicating wirelessly with the main control system via a wireless communication network. - View Dependent Claims (9, 10, 11)
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12. A method for heating vessels of a piping system by a heat trace system, wherein the heat trace system comprises:
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a main control system comprising an AC electrical power source; a plurality of heat trace elements that are each adjacent to a vessel of the piping system, and wherein the plurality of heat trace elements are connected to the AC electrical power source of the main control system to conduct AC current from the AC electrical power source; and a plurality of wireless modules distributed throughout the piping system, wherein each of the plurality of wireless modules; is connected to and powered by an associated heat trace element of the plurality of heat trace elements, comprises an AC-to-DC converter that converts AC voltage from the associated heat trace element to DC voltage; comprises a switch connected to the AC-to-DC converter; comprises a controller for controlling the switch; comprises a supercapacitor connected to the AC-to-DC converter via the switch, wherein the supercapacitor is for storing energy from the associated heat trace element that is coupled to the supercapacitor by the AC-to-DC converter and the switch, and wherein the controller controls the switch based on a voltage across the supercapacitor; the method comprising; storing energy, by each wireless module, in the supercapacitor of the wireless module, from a voltage difference across the wireless module'"'"'s associated heat trace element; powering each wireless module with the stored energy from the supercapacitor of the wireless module; and communicating, by each wireless module with the main control system, wirelessly via a wireless communication network. - View Dependent Claims (13, 14, 15)
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16. A system comprising:
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a piping system comprising a plurality of vessels; a main control system comprising a programmable controller and an electrical power source, wherein the electrical power source comprises a plurality of voltage regulators; a plurality of heat trace elements, wherein each of the plurality of heat trace elements is adjacent to at least one of the plurality of vessels of the piping system, and wherein each of the plurality of heat trace elements is connected to one of the voltage regulators; and a plurality of wireless modules distributed throughout the piping system, wherein each wireless module; is connected to and powered by an associated heat trace element of the plurality of heat trace elements; comprises an energy storage device connected to the associated heat trace element for storing energy from the associated heat trace element, wherein the energy stored by the supercapacitor from the associated heat trace element is for powering the wireless module; and comprises an RF module for communicating wirelessly with the main control system via a wireless communication network, wherein the RF module of each wireless module wirelessly transmits charge level data indicative of the charge level of the energy storage device of the wireless module to the main control system; and wherein the programmable controller of the main control system is programmed to; compare the charge levels of the energy storage devices of the wireless modules to desired charge levels based on the charge level data received from the wireless module; and control an output voltage for one or more of the voltage regulators based on the comparison to thereby change the voltage across one or more of the heat trace elements.
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17. A heat trace system for heating vessels in a piping system, the heat trace system comprising
a main control system comprising a programmable controller and an electrical power source, wherein the electrical power source comprises a plurality of voltage regulators; -
a plurality of heat trace elements, wherein each of the plurality of heat trace elements is adjacent to at least one of the vessels of the piping system, and wherein each of the plurality of heat trace elements is connected to one of the plurality of voltage regulators; and a plurality of wireless modules distributed throughout the piping system, wherein each wireless module; is connected to and powered by an associated heat trace element of the plurality of heat trace elements; comprises an energy storage device connected to the associated heat trace element for storing energy from the associated heat trace element, wherein the energy stored by the energy storage device from the associated heat trace element is for powering the wireless module; and comprises an RF module for communicating wirelessly with the main control system via a wireless communication network, wherein the RF module of each wireless module wirelessly transmits charge level data indicative of the charge level of the energy storage device of the wireless module to the main control system; and wherein the programmable controller of the main control system is programmed to; compare the charge levels of the energy storage devices of the wireless modules to desired charge levels based on the charge level data received from the wireless modules; and control an output voltage for one or more of the voltage regulators based on the comparison to thereby change the voltage across one or more of the heat trace elements.
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18. A method for a heat trace system that heats vessels of a piping system, wherein the heat trace system comprises:
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a main control system comprising an electrical power source that comprises a plurality of voltage regulators; a plurality of heat trace elements that are each adjacent to a vessel of the piping system, and wherein the plurality of heat trace elements are connected to the one of the plurality of voltage regulators; and a plurality of wireless modules distributed throughout the piping system, wherein each of the plurality of wireless modules is connected to and powered by an associated one of the plurality of heat trace elements, the method comprising; storing energy, by each wireless module, in a energy storage device of the wireless module, from a voltage difference across the wireless module'"'"'s associated heat trace element; powering each wireless module with the stored energy from the energy storage device of the wireless module; wirelessly transmitting, by each wireless module, charge level data indicative of the charge level of the energy storage device of the wireless module to the main control system via a wireless communication network; comparing, by the main control system, the charge levels of the energy storage devices of the wireless modules to desired charge levels based on the charge level data received from the wireless modules; and controlling, by the main control system, an output voltage for one or more of the voltage regulators based on the comparison to thereby change the voltage across one or more of the heat trace elements.
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Specification
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Current AssigneeChromalox Incorporated (Spirax-Sarco Engineering PLC)
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Original AssigneeChromalox Incorporated (Spirax-Sarco Engineering PLC)
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InventorsHeiligenstein, Adam
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Primary Examiner(s)PASCHALL, MARK H
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Application NumberUS14/618,217Publication NumberTime in Patent Office742 DaysField of Search219/494, 219/497, 219/213, 219/535, 219/483, 219/486, 392/468US Class Current1/1CPC Class CodesE03B 11/00 Arrangements or adaptations...E03B 7/12 by preventing freezingF16L 53/30 Heating of pipes or pipe sy...F16L 53/38 using elongate electric hea...G01F 1/7044 using thermal tracersH05B 1/0244 Heating of fluids H05B1/024...H05B 1/0297 Heating of fluids for non s...
