BR102014013110A2 - LOW WATER HEATER ENERGY CONSUMPTION AND HIGH ENERGY EFFICIENCY - Google Patents

Abstract

SUMMARY “LOW ENERGY CONSUMPTION AND HIGH ENERGY EFFICIENCY WATER HEATER”. The present invention patent application dealt with a water heater, with extremely low electrical energy consumption and high energy efficiency. Using a new method or process to capture and reuse the thermal energy available in the waste water, and transfer it to the heater's water supply circuit. Consisting of a thermal energy capture module (3) installed on the floor, a thermal energy transfer module (1) installed at the water supply inlet, and a control module (2) responsible for monitoring and adjusting electronics of the entire heating unit. Built in a single set for installation in the same room, not requiring specialized labor for installation by a qualified professional, regardless of variations, locations or constructive forms of the heater modules.

Description

“LOW WATER HEATER AND HIGH ENERGY EFFICIENCY”.

[001] It seeks the present patent application for a model of extremely low energy consumption and high energy efficiency water heater, intended for heating water for showers, sinks, sinks and other such systems. Based on a new process or method of reusing thermal energy, available in the wastewater itself during showering, or water from faucets in kitchen sinks, sinks or others. And the simultaneous transfer of this energy to the water supply circuit of the heater.

In the present state of the art, we find electric water heaters known as showers or electric heaters, which use the principle of water heating by the Joule effect, generated from the circulation of electric current through the resistance installed inside the heater.

We also find inductive water heaters that use the Foucault effect as a heating principle, where a metal core is heated through electromagnetic oscillation generated from an inductor installed inside the heater.

[004] Another model found on the current market is gas water heaters, which use as a heating principle the combustion of gas which in the convection of heated gases transfers thermal energy to water through a exchanger installed in the heater.

Also in the present state of the art, we find solar water heaters, which use as a principle of water heating the incidence of solar rays on their thermal energy capture plates installed on roofs and roofs responsible for the transfer of thermal energy. to water, which circulates within it. Still describing the state of the art, we find water heaters known as heat pumps, which use as a heating principle the capture of thermal energy in the air through a fan / evaporator assembly installed outside the home, and transfers it. for water in the condenser unit installed inside a boiler or water tank, thanks to the refrigerant pumping through the compressor and other peripherals such as filter, expansion valve and other elements necessary for the system.

In order to innovate this market, the author has developed the present invention, which is a method of efficient recovery of the thermal energy contained in the wastewater, consisting of a heat pump responsible for capturing available thermal energy in the water. and the transfer to the heater water supply circuit.

[008] This whole process is performed in a platform-shaped evaporator installed on the floor of the enclosure below the shower, and can also be installed at the base of the sink or sink basin, and is responsible for capturing the thermal energy contained in the water. Disposal, this occurs during expansion of the refrigerant after passing through the expansion valve and pumping through the compressor, passing through the condenser installed in the water supply circuit, where there is the transfer of thermal energy to water, until then contained in the fluid raising your temperature.

[009] The equipment also has other essential elements such as filter drier, piping, service valves, flow switch, temperature sensor, controller and others necessary for the system operation, detail already present in the state of the art, whose object The main one is the capture and reuse of the thermal energy available in the wastewater and transfer to the heater water supply circuit. [010] The heater is designed so that the wastewater does not freeze during thermal energy withdrawal by the evaporator on the platform, reducing its temperature slightly above the freezing point of water at 0 ° C.

[011] The heater differs from traditional heat pumps in that it is more compact, in the same enclosure, has minimal peripherals, no thermally insulated boiler or accumulators, no fans, brackets and chassis present in traditional heat pumps , which draw thermal energy from the air, be easy to install hydraulic and electrical, and be supplied in a single set ready for installation.

[012] The heater stands out innovatively from the other heaters cited in the current state of the art for its high energy efficiency, extremely low power consumption to collect available thermal energy in the disposal and transfer water to the input circuit. heater water, consuming less than 1/5 of the available thermal energy.

[013] For the sake of a better understanding of the concept, and by way of example only, let us consider that the water flow rate in the heater is 1 liter per minute with water at 18 ° C, and that the temperature of the wastewater can be evaporator at 2 QC, without freezing, will then be available through the 16 Kcal per minute condenser to transfer water to the inlet circuit, which will raise its temperature to 34 QC, so in the second cycle the water temperature Disposal can be reduced again in the evaporator to 2 ° C without freezing, which will be available in this cycle in the 32 Kcal per minute condenser for transfer to the inlet circuit water, now raising the water temperature to 50 ° C where The controller will control the compressor to maintain the temperature previously set by the user, and in this example system losses were not considered.

[014] We can highlight in this equipment that all heater accessories and equipment, are in a single enclosure and form a single module, not being necessary installation by a specialized professional, which makes it a practical equipment, low cost and easy. installation in any type of property compared to traditional heat pumps, which necessarily need to be installed outdoors, and by qualified and qualified professionals.

[015] Another noteworthy feature is the relationship between the available thermal energy, in relation to the electric energy consumed in the heater to perform the work, called COP (Coefficient of Performance) of this heater, which differentiates it from other equipment and makes it the most efficient available on the market today. This COP is obtained thanks to the method proposed here, of reusing the available thermal energy in the wastewater itself, requiring the minimum energy required by the compressor to transfer energy to the water inlet circuit, reaching very high Performance Coefficient.

[016] Regarding the components that make up the heating system, the compressor is driven by a high-output direct current or alternating current motor that is responsible for pumping and circulating the refrigerant. Therefore, it uses high efficiency non-ozone-aggressive refrigerant and low impact Greenhouse Gases (GHG). The compressor may also have several configurations available on the market, preferably using the best performance.

[017] In the list of components that make up the heating system, the electronic controller manages and controls the entire heating unit, and can be presented in conventional or advanced version. Being the conventional model only for adjustment and configuration of the heater variables, such as temperature control and consequent adjustment of fluid flow through the control of compressor speed as a function of temperature and water flow.

[018] Advanced model also includes touch screen, chromotherapy and entertainment functions, audio playback, radio tuner, television systems, images, videos, wireless networks, telephony, communication, indication and monitoring of water inlet and outlet temperature variables or consumption information, bath time and others.

[019] Another positive point of the heater is the conservation and rational use of energy resources, representing a significant reduction in energy consumption on the planet and a reduction in greenhouse gas emissions and lower infrastructure investments in the energy grid.

[020] The heater proposed and required here has been thoroughly tested and improved to have its practical functionality proven, as well as to withstand and adapt to possible variations in compressor, gas or refrigerant models, evaporators, condensers, expansion valves, motors and other devices to be used in the heater.

[021] Another variant that the heater may present, is related to the type of equipment, constructive form or method of removal of thermal energy from the wastewater. It can also be performed by the absorption method or by the use of new refrigerants that may be developed in the future. This does not detract from the inventive principle set forth herein which deals with the method or process of reusing the thermal energy of waste water through the use of refrigerants for the removal of thermal energy near the freezing temperature of water.

[022] The attached figures and the explanatory details given below are intended for precise understanding and are provided with alpha numeric references.

[023] Figure 1 shows an isometric perspective front view of the shower heater.

[2] Figure 2 shows an isometric perspective rear view of the shower heater.

[3] Figure 3 shows a view of the basic heater operating flow chart.

[026] Figure 4 shows an example view in one of the many ways the front set can be presented.

[027] According to figures 1; 2; and 3 we will detail the present water heater requirement in basically three modules for ease of understanding, namely: thermal energy capture module

(3), mounted on the floor of the enclosure below the shower or shower (1c), consisting of an evaporator (3a), a compressor (3b), fluid expansion valve (3c), filter (3d) with the upper surface the overlapping rubber drop pickup module (3) for support and isolation between the user's feet and the evaporator metal base (3a); thermal energy transfer module (1) composed of an internal condensing unit (1a) installed after quick connection of water (1d), lock (1e) and flow switch (1b), before the shower (1c) and can optionally contain a low power resistor for initial heating support and small water temperature compensation for very cold regions; and finally the microprocessor control module (2) responsible for compressor speed adjustment (3b), variable monitoring and water heater protection, these being the controlled variables in the basic version controller (2), and additional entertainment functions. selectable visual, sound, whirlpool and / or chromatic photo therapy on touch screen for advanced controller version (2). In addition to the main modules listed above, the equipment is comprised of some basic accessories such as flexible profile lined flexible hose (4a) for finishing and thermal insulation, mains plug (2a), service valves, , electrical cable for connection between compressor (3b), microprocessor control module (2) and parts for finishing and protection.

[028] At heater fluid circuit interconnections, we will by definition adopt an inlet and an outlet connection for each component and the direction of flow of the refrigerant, starting with the outlet of the fluid expansion valve (3c ), which is connected to the evaporator input (3a) and its output, connected to the compressor input (3b), which has its output connected to the condenser input (1a) and this one with its output connected to the filter input. dryer (3d) which in turn connects its outlet to the expansion valve inlet (3c), thereby closing the water heater refrigerant circuit.

Claims (10)

1. “LOW WATER HEATER HEATER AND HIGH ENERGY EFFICIENCY” is characterized by the process or method of capturing and reusing available thermal energy in the wastewater and transferring it to the heater water supply circuit, regardless of variations, location or construction of each module, a process performed by the thermal energy capture module (3), thermal energy transfer module (1), and control module (2). 2. “LOW WATER HEATER HEATER AND HIGH ENERGY EFFICIENCY” according to claim 1, characterized in that its thermal energy capture module (3) has a dryer filter (3d) coupled to the expansion valve (3c) , responsible for the expansion of the refrigerant in the evaporator (3a) coupled next to the motor compressor (3b), which pumps the refrigerant to the thermal energy transfer unit (1), where the thermal energy contained in the refrigerant is transferred and consequently heating the feed water. 3. "LOW POWER WATER HEATER AND HIGH ENERGY EFFICIENCY" according to claim 1, characterized in that the thermal energy transfer module (1) consists of a quick connect (1d), lock (1e), flow switch (1b), internal condensing unit (1a) responsible for condensation of refrigerant and transfer of thermal energy to the supply water, raising its temperature to be then sprayed by the shower or shower (1c). 4. “LOW POWER WATER HEATER AND HIGH ENERGY EFFICIENCY” according to claim 1, characterized in that the control module (2) has the entire control and power electronic circuitry internally for monitoring the power variables. temperature, flow and other additional functions such as controlling the compressor (3b) by changing its torque and rotation, or opening the expansion valve (3c), or even the water inlet flow, as per user and version preset of the heater. 5. “LOW POWER WATER HEATER AND HIGH ENERGY EFFICIENCY” according to claim 1, characterized in that the heater has in the advanced control version (2) entertainment functions such as audio, video, radio, television systems , internet access, wireless communication networks, telephony, chromotherapy functions, and even built-in pressurizer in the case of available low water or whirlpool facilities. 6. “LOW WATER HEATER HEATER AND HIGH ENERGY EFFICIENCY” according to claim 1, characterized in that the thermal energy capture modules (3) and thermal energy transfer module (1) are interconnected via flexible hoses (4a), coated with thermal insulation profile (4), for self-adhesive finishing and wall mounting. 7. “LOW POWER WATER HEATER AND HIGH ENERGY EFFICIENCY” according to claim 1, characterized by the thermal energy capture (3), thermal energy transfer (1) and control (2) modules, they form a single set and are grouped and installed in the same room, readily manufactured for electrical and hydraulic connection, without the need for infrastructure investments, using water controls (5) and traditional or existing connections at home. 8. "LOW WATER HEATER HEATER AND HIGH ENERGY EFFICIENCY" according to claim 1, characterized in that it has its thermal energy capture module (3), consisting internally of a motor compressor (3b). driven by direct current motor, permanent magnet motor or asynchronous motor. 9. "LOW WATER HEATER HEATER CONSUMPTION AND HIGH ENERGY EFFICIENCY" according to claim 1, characterized in that, as a method of mechanical compression of the refrigerant, the various forms available on the market may be, as an alternative, centrifugal compression model , screw, piston, vanes, lobes, gears, scroll or others specially manufactured for such purpose or to be developed in the future. 10. “LOW WATER HEATER HEATER AND HIGH ENERGY EFFICIENCY” according to claim 1, characterized in that the process or method of capturing and reusing available thermal energy in the wastewater and transferring it to the water supply circuit heater, be applied to showers, sinks, sinks or other household systems, hotel chains, spas, gyms, commercial or industrial.