DK3049733T3

DK3049733T3 - FLUID HEATING DEVICE

Info

Publication number: DK3049733T3
Application number: DK15827258.3T
Authority: DK
Inventors: Andrea Rossi
Original assignee: Andrea Rossi
Priority date: 2014-08-01
Filing date: 2015-07-28
Publication date: 2018-01-02
Also published as: LT3049733T; SI3049733T1; PL3049733T3; AU2015296800A1; WO2016018851A1; ES2652548T3; CY1119675T1; NO2788577T3; JP2017523369A; BR112016013488A2; EP3049733A1; MX2016002006A; RS56749B1; CN106133457B; CA2920500C; EP3049733A4; HRP20171960T1; EP3049733B1; HUE036258T2; MX348291B

Description

DESCRIPTION

CROSS-REFERENCE TO RELATED APPLICATIONS

[0001] This application claims the benefit of the August 1, 2014 priority date of U.S. Application No. 61/999, 582.

FIELD OF DISCLOSURE

[0002] This disclosure relates to heat transfer systems, and in particular to devices for transferring heat to a fluid.

BACKGROUND

[0003] Many heat transfer systems use hot fluids as a heat transfer medium. Such systems include a heat generator for generating heat, a heat transfer medium in thermal communication with the energy source, and a pump to move the heated medium to wherever the heat is needed. Because of its high heat capacity and its abundance, a common heat transfer fluid is water, both in its liquid and gas phase.

[0004] A variety of heat generators are in common use. For instance, in nuclear power plants, nuclear fission provides energy for heating water. There also exist solar water heaters that use solar energy. Also known in the art are self contained heat sources for heating food and drink wherein an energetic nanolaminate is electrically initiated via resistive heating, see for instance US 2008/0131316 A1. However, most heat transfer sources rely on an exothermal chemical reaction, and in particular, on combustion of some fuel.

SUMMARY

[0005] In one aspect, the invention features an apparatus for heating fluid, the apparatus including a tank for holding fluid to be heated, and a fuel wafer in fluid communication with the fluid, the fuel wafer including a fuel mixture including reagents and a catalyst, and a heat source in thermal communication with the fuel mixture and the catalyst. The heat source is an electrical resistor. According to the invention, the fuel mixture includes lithium and lithium aluminum hydride, those in which the catalyst includes a group 10 element, such as nickel in powdered form, or in any combination thereof.

[0006] In other embodiments, the catalyst in powdered form, has been treated to enhance its porosity. For example, the catalyst can be nickel powder that has been treated to enhance porosity thereof. The apparatus can also include an electrical energy source, such as a voltage source and/or current source in electrical communication with the heat source.

[0007] Among the other embodiments are those in which the fuel wafer includes a multi-layer structure having a layer of the fuel mixture in thermal communication with a layer containing the heat source.

[0008] In yet other embodiments, the fuel wafer includes a central heating insert and a pair of fuel inserts disposed on either side of the heating insert.

[0009] A variety of tanks can be used. For example, in some embodiments, the tank includes a recess for receiving the fuel wafer therein. Among these are embodiments in which the tank further includes a door for sealing the recess. In yet other embodiments the tank includes a radiation shield. According to the invention, the apparatus further includes a controller in communication with the voltage source. Among these are controllers that are configured to vary the voltage in response to temperature of the fluid to be heated.

[0010] These and other features of the invention will be apparent from the following detailed description and the accompanying figures, in which:

BRIEF DESCRIPTION OF THE FIGURES

[0011] FIG. 1 shows a heat transfer system having a heat source; FIG. 2 is a cut-away view of the heat source in FIG. 1; FIG. 3 is a cross-section of the wafer for use in the heat source of FIG. 2; FIG. 4 shows an exemplary resistor in the central layer of the wafer shown in FIG. 3. FIG. 5 shows the heat source of FIG. 1 operating with a conventional furnace. FIG. 6 shows plural heat sources like that in FIG. 2 connected in series. FIG. 7 shows plural heat sources like that in FIG. 2 connected in parallel.

DETAILED DESCRIPTION

[0012] Referring to FIG. 1, a heat transfer system 10 includes a pipe 12 for transporting a heated fluid in a closed loop between a heat source 14 and a thermal load 16. In most cases, for example where there is hydraulic resistance to be overcome, a pump 18 propels the heated fluid. However, in some cases, such as where the heated fluid is steam, the fluid's own pressure is sufficient to propel the fluid. Atypical thermal load 16 includes radiators such as those commonly used for heating interior spaces.

[0013] As shown in FIG. 2, the heat source 14 is a tank 20 having a lead composite shield, an inlet 22 and an outlet 24, both of which are connected to the pipe 12. The interior of the tank 20 contains fluid to be heated. In many cases, the fluid is water. However, other fluids can be used. In addition, the fluid need not be a liquid fluid but can also be a gas, such as air.

[0014] The tank 20 further includes a door 26 that leads to a receptacle 28 protruding into the tank 20. Radiating fins 30 protrude from walls of the receptacle 28 into the tank 20. To maximize heat transfer, the receptacle 28 and the fins 30 are typically made of a material having high thermal conductivity, such as metal. A suitable metal is one not subject to corrosion, such as stainless steel.

[0015] The receptacle 28 holds a multi-layer wafer 32 for generating heat. A voltage source 33 is connected to the wafer 32, and a controller 35 for controlling the voltage source 33 in response to temperature of fluid in the tank 20 as sensed by a sensor 37.

[0016] As shown in FIG. 3, the multilayer fuel wafer 32 includes a heating section 34 sandwiched between two fuel sections 36, 38. The heating section 34 features a central layer 40 made of an insulating material, such as mica, that supports a resistor 42. It should be noted that other heating sources can be used, including heat sources that rely on combustion of, for example, natural gas, as well as heat sources that rely on electrical induction. The use of gas thus avoids the need to have a source of electrical energy for initiating the reaction.

[0017] FIG. 4 shows an exemplary central layer 40 having holes 44 through which a resistive wire 42 has been wound. This resistive wire 42 is connected to the voltage source 33. First and second insulating layers 46, 48, such as mica layers, encase the central layer 40 to provide electrical insulation from the adjacent fuel sections 36, 38.

[0018] Each fuel section 36, 38 features a pair of thermally conductive layers 50, 52, such as steel layers. Sandwiched between each pair of conductive layers 50, 52 is a fuel layer 54 that contains a fuel mixture having nickel, lithium, and lithium aluminum hydride LiAIH4 ("LAH"), all in powdered form. Preferably, the nickel has been treated to increase its porosity, for example by heating the nickel powder to for times and temperatures selected to superheat any water present in micro-cavities that are inherently in each particle of nickel powder. The resulting steam pressure causes explosions that create larger cavities, as well as additional smaller nickel particles.

[0019] The entire set of layers is welded together on all sides to form a sealed unit. The size of the wafer 32 is not important to its function. However, the wafer 32 is easier to handle if it is on the order of 0,85 cm (1/3 inch) thick and 30,5 cm (12 inches) on each side. The steel layers 50, 52 are typically 1 mm thick, and the mica layers 40, 48, which are covered by a protective polymer coating, are on the order of 0.1 mm thick. However, other thicknesses can also be used.

[0020] In operation, a voltage is applied by the voltage source 33 to heat the resistor 42. Heat from the resistor 42 is then transferred by conduction to the fuel layers 54, where it initiates a sequence of reactions, the last of which is reversible. These reactions, which are catalyzed by the presence of the nickel powder, are:

[0021] Once the reaction sequence is initiated, the voltage source 33 can be turned off, as the reaction sequence is self-sustaining. However, the reaction rate may not be constant. Hence, it may be desirable to turn on the voltage source 33 at certain times to reinvigorate the reaction. To determine whether or not the voltage source 33 should be turned on, the temperature sensor 37 provides a signal to the controller 35, which then determines whether or not to apply a voltage in response to the temperature signal. It has been found that after the reaction has generated approximately 6 kilowatt hours of energy, it is desirable to apply approximately 1 kilowatt hour of electrical energy to reinvigorate the reaction sequence.

[0022] Eventually, the efficiency of the wafer 32 will decrease to the point where it is uneconomical to continually reinvigorate the reaction sequence. At this point, the wafer 32 can simply be replaced. Typically, the wafer 32 will sustain approximately 180 days of continuous operation before replacement becomes desirable.

[0023] The powder in the fuel mixture consists largely of spherical particles having diameters in the nanometer to micrometer range, for example between 1 nanometer and 100 micrometers. Variations in the ratio of reactants and catalyst tend to govern reaction rate and are not critical. However, it has been found that a suitable mixture would include a starting mixture of 50% nickel, 20% lithium, and 30% LAH. Within this mixture, nickel acts as a catalyst for the reaction, and is not itself a reagent. While nickel is particularly useful because of its relative abundance, its function can also be carried out by other elements in column 10 of the periodic table, such as platinum or palladium.

[0024] FIGS. 5-7 show a variety of ways to connect the heat source 14 in FIG. 1.

[0025] In FIG. 5, the heat source 14 is placed downstream from a conventional furnace 56. In this case, the controller 35 is optionally connected to control the conventional furnace. As a result, the conventional furnace 56 will remain off unless the output temperature of the heat source 14 falls below some threshold, at which point the furnace 56 will start. In this configuration, the conventional furnace 56 functions as a back-up unit.

[0026] In FIG. 6, first and second heat sources 58, 60 like that described in FIGS. 1-4 are connected in series. This configuration provides a hotter output temperature than can be provided with only a single heat source 58 by itself. Additional heat sources can be added in series to further increase the temperature.

[0027] In FIG. 7, first and second heat sources 62, 64 like that described in FIGS. 1-4 are connected in parallel. In this configuration, the output volume can be made greater than what could be provided by a single heat transfer unit by itself. Additional heat transfer units can be added in parallel to further increase volume.

[0028] In one embodiment, the reagents are placed in the reaction chamber at a pressure of 3-6 bar and a temperature of from 400 C to 600 C. An anode is placed at one side of the reactor and a cathode is placed at the other side of the reactor. This accelerates electrons between them to an extent sufficient to have very high energy, in excess of 100 KeV. Regulation of the electron energy can be carried out by regulating the electric field between the cathode and the anode.

[0029] Having described the invention, and a preferred embodiment thereof, what I claim as new and secured by letters patent is:

REFERENCES CITED IN THE DESCRIPTION

This list of references cited by the applicant is for the reader's convenience only. It does not form part of the European patent document. Even though great care has been taken in compiling the references, errors or omissions cannot be excluded and the EPO disclaims all liability in this regard.

Patent documents cited in the description • US61999582A IOQQ11 • US20Q80131316A1 fOQQ41

Claims

A fluid heating device, the device comprising a tank (20) for containing fluid to be heated and a fuel wafer (32) in fluid communication with the fluid, the fuel wafer (32) including a fluid mixture comprising contains reagents and a catalyst, and a heat source (14) in thermal communication with the fuel mixture and the catalyst, the heat source (14) comprising an electrical resistor (42), the tank (20) being configured to contain fluid to be heated, wherein the fuel wafer (32) is configured to be in thermal communication with the fluid, the resistor (42) being configured to be coupled to a voltage source (33), the device further comprising a control unit (35) in communication with the voltage source (33); ) and a temperature sensor (37), wherein the fuel mixture comprises lithium and lithium aluminum hydride, wherein the catalyst comprises a group 10 element, wherein the control unit (35) is configured to monitor a temperature from the temperature sensor (37), and based at least in part on the temperature, for setting a new thrust in a reaction in the fuel mixture, the renewed thrust in the reaction comprising varying a voltage of the voltage source (33).

The device of claim 1, wherein the catalyst comprises nickel powder.

The device of claim 2, wherein the nickel powder has been treated to increase its porosity.

The device of claim 1, wherein the fuel wafer (32) comprises a multilayer structure having a layer of the fuel mixture in thermal communication with a layer containing the electrical resistor (42).

The device of claim 1, wherein the fuel wafer (32) comprises a central heating insert and a pair of fuel inserts located on both sides of the heating insert.

The device of claim 1, wherein the tank (20) comprises a notch for receiving the fuel wafer (32) therein.

The device of claim 6, wherein the tank (20) further comprises a door (26) for sealing the notch.

The device of claim 1, wherein the tank (20) comprises a radiation shield.

The device of claim 1, wherein the reaction in the fuel mixture is at least partially reversible.

The device of claim 9, wherein the reaction comprises reacting lithium hydride with aluminum to obtain hydrogen gas.