SK8541Y1 - Thermoelectric heat pump - Google Patents

Abstract

The thermoelectric heat pump utilizes a series-parallel connection of the Peltier phenomenon thermoelectric cells (1) connected to an electro-photovoltaic panel (6), which is designed for the preparation of hot or cold water in a storage vessel (14) in particular in low energy and passive houses . The thermoelectric heat pump by means of heat exchangers accumulates heat energy in the water in a storage tank (14) which is then pumped into the ceiling, wall or floor heating / cooling pipes. The technical solution belongs to alternative energy sources.

Description

Technical field

The technical solution belongs to the group of alternative sources of heating and cooling of residential and industrial premises and it primarily uses solar radiation for heating or cooling, which supplies thermoelectric cells - Peltierovjav - by means of electrophotovoltaic panels. An installed thermoelectric heat pump can provide a stable indoor or industrial room temperature of 25 ° C ± 5 ° C at an ambient ambient air temperature of +40 ° C to -20 ° C, provided that the space is appropriately insulated and has the correct distribution of hot water distribution.

BACKGROUND OF THE INVENTION

At present, heat pumps, with an electric compressor, are used to heat / cool the living quarters, utilizing the latent state of the substance to supply thermal energy when heating is required or heat energy is consumed in case of cooling. These devices cannot be directly connected to the PV collectors due to the unstable performance of the PV panels.

The essence of the technical solution

The thermoelectric heat pump comprises TBC thermoelectric cells composed of tellurium and bismuth between ceramic plates utilizing the Peltier effect, where, when connected to a DC power source, one side of the thermoelectric cell warms while the other side cools. These are interposed between two types of aluminum heat exchangers, two of which are continuous and one circulating, in which water with antifreeze flows. When the polarity of the voltage on the thermoelectric cells changes, the temperatures on the ceramic contact surfaces are reversed, which ensures heating and cooling by simply connecting the contactor. Depending on the intensity of the sunshine, the thermoelectric heat pump generates heat, directly feeds the resistive load, and does not require the minimum power of the photovoltaic panels to function, and therefore operates throughout the day, making maximum use of all solar energy.

Figures no. 2, 3, 4, 5 determine the design of the tenroelectric unit.

A heat transfer medium, e.g. water for indoor heat exchangers. The indoor circulating heat exchanger is used to transfer or remove heat from an accumulation vessel from which at least one outlet for floor, wall heating is conducted. Indoor continuous heat exchanger with the desire to transmit or take heat to or from the outside, for which two types of outdoor heat exchangers are used, one for heating to extract heat from the surrounding area should be on the sunny side and poor for cooling best in the shade even out of the sun's rays throughout the day, which is further equipped with a fan for more efficient cooling. The thermoelectric heat pump comprises at least one of both types of outdoor heat exchangers. The thermoelectric heat pump comprises at least one tetraoelectric unit.

This solution does not require the AC voltage of the distribution network, and therefore it is advantageous to use it for heating or cooling rooms without connection to the power supply. Electricity is supplied directly from the sun by using electro-photovoltaic panels, the energy of which is directly consumed to heat or cool the water in the storage tank, to drive the pumps, valves and control unit, and can be stored in electric accumulators from which night or frosty sunny days. If a distribution network is available, the DC power supply can be used via a diode separator and circuit breakers.

The thermoelectric heat pump includes a control unit that measures at least one room temperature, at least one room wall temperature, the storage tank temperature, the ambient temperature of the thermoelectric heat pump location, the operation of the at least one circulation pump for indoor and outdoor heat exchangers. energy consumption from the distribution network, the condition of the electric accumulator battery, controls the contactor to change the polarity of the thermoelectric cells and the valve that switches the heat transfer medium of the external heat exchangers. All data and states of measured values can be sent via GSM data network and via SMS messages or stored in a computer.

The advantage of a thermoelectric heat pump is that it can be replaced with existing heat pumps as the connection entitlement is compatible.

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Overview of drawings with drawings

Fig. 1 - Thermoelectric pump wiring diagram.

Fig. 2 - Thermal insulation from styrodur with milled holes serves to prevent heat escape from components.

Fig. 3 - interior heat exchanger no. 1 - bottom and roll; are aluminum milled profiles. The continuous heat transfer medium enters at two locations on one side and exits at two locations on the other side.

Fig. 4 - Interior heat exchanger no. 2 - bottom and top. are aluminum milled profiles. The circulating, heat transfer medium enters at one point on one sulfur and exits at a second point on the same side

Fig. 5 The mounting mechanism serves for the structural mounting of two indoor heat exchangers no. 1 - bottom of interior heat exchangers no. i - top and one interior heat exchanger no. 2 - bottom and interior heat exchanger no. 2 - top

EXAMPLES

The tetmoelectric heat pump has two basic parts: The first part consists of a thermoelectric unit 1 with water distribution pipes and a C2 pump for wall or wall heating. the second part consists of two heat exchangers: a heat exchanger, a cold water 12 and a hot water cooler 13, through which the water is pressed by means of a pump C1 and is regulated as required by the cooling or heating system Valve VI.

Constructed prototype ternioelekiriekého heat pump, uses thermoelectric cells type TEC1-12'730, with a power of 350 W and electropotovoltické panels 6 with an output of 350 Wp. Thermoelectric cells as well as totovoltaic collectors can be combined according to the power supply requirements.

The first part consists of two types of interior heat exchange heat in the heat, namely the interior heat exchanger no. 1 - bottom 2 of interior heat exchanger no. 1 - top 2a and interior heat exchanger no. 2 - bottom 3, interior heat exchanger no. 2 - the top 3a, between which the thermoelectric element 1 is placed, further by the mounting mechanism 4 and the thermal insulation 5.

Interior heat exchanger no. 1 - bottom 2, interior heat exchanger no. The top 2a of the tetmoelectric unit 13 is continuous, i.e. water enters at least one opening on one side and exits at least one opening on the other side. It serves for heat exchange in the space of the building where the pump C1 is the water led through the tubes according to the position of the valve VI to separate heat exchangers for heating through the cold water heat exchanger 12 and for cooling through the hot water cooler 13.

Interior heat exchanger no. 2 - bottom 3, interior heat exchanger no. 2 - the top 3a of the tetmoelectric unit 11 is circulating, i.e. the water enters it through at least one opening on one side, rotates 180 ° and exits through at least one opening on the same side. This exchanger is used to pass heat to the storage tank. 14th

The exterior part consists of two separate heat exchangers which are stored outdoors, a hot water cooler 13 for cooling and a cold water heat exchanger 12 for heating, which allows to maximize the efficiency of the heat pump for heating and cooling.

The thermoelectric heat pump pumps the thermal energy stored in the heat transfer medium from the exterior to the interior and vice versa, when the polarity of the direct current that flows through the tenelelectric cells 3 changes. The directional switching is provided by the control unit 30 via a contactor.

The thermoelectric heat pump pumps the heat energy from the exterior part to the interior part 11, on the other hand, by means of heat transfer therethrough. multilayer construction of tetmoelectric cells 1. A thermoelectric heat pump does not require electrical power for this process.

The exterior part of the ten-electric heat pump uses DC ventilators for more efficient heat exchange, which are fed from a common DC voltage via the circuit breaker.

The cooling water heat exchanger 12 is oriented to the south side of the object and, if possible, is constantly illuminated by a sunbeam during the day. This part serves to heat the heat carrier medium and the thermal energy is obtained mainly from the solar thermal energy. The control unit 10 provides, via valve VI, the desired direction of the heat-carrying medium for heating.

The cooling water cooler 13 is oriented to the north cardinal side of the object and, if possible, is stored in the shade, away from sunlight throughout the day. This part serves for more efficient cooling of the heat carrier medium in case of need of cooling. The control unit 10 provides the desired direction of the heat transfer medium through the valve VI for cooling.

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The hectro-voltaic panels 6 are connected to the electric accumulators 7 via a circuit breaker and accumulate excess energy not just consumed by the thermo-electro unit 11 for energy consumption at night or for less sunny days.

The hectro-lithium panels 6 can be connected to a DC / AC converter via a circuit breaker and supply excess energy not just consumed by the ten-electric unit 11 to the 230V AC power distribution.

The thermoelectric heat pump is connected to the accumulators 7 via a circuit breaker, it does not require connection to the distribution network.

The control unit 10 can measure the energy produced! from the electrical panels 6, the energy supplied by the green-electric panels 6 to the electric accumulators 7 W1, the energy supplied from a 9 W2 DC power source powered by 230 V AC, (400 V AC), and the generated energy from the 6 W3 electrical photovoltaic panels. The control unit 10 further changes the outside ambient temperature - TI, the temperature of the cold water heat exchanger 12 - Ύ2 for heating, the temperature of the hot water cooler 13 - T4, the water temperature in the storage tank 14 - T3, all room air temperatures in the building - Tmi to Tmx. room wall temperatures-Ts1 to Ts x, and the ambient room temperature of the thermocouple unit 11 -T5.

The control unit 10 can monitor the status of the distribution network - Dig. input 1, fan failure Vent 1 Dig. input 2, DC source fault 9 - Dig. input 3, status of the connected battery 7 Dig. input 4 and optional 3 digital potential-free inputs - Dig. input 5 to Dig, input 7.

A thermoelectric heat pump of this type can be connected directly to the electro-electric panels 6 directly without DC / DC or DC / AC power converters and thus utilize renewable energy sources without electrical losses; in DC / DC or DC / AC converters. It is not surprising that the power input of the heat thermoelectric pump is greater than or equal to the power of the electrophotovoltaic panels 6 and at the same time the connection of the thermocouple cells 1! of the photovoltaic panels 6 does not exceed the lines, the working voltage of the thermoelectric cells L

The power to the thermoelectric heat pump can be connected via an isolation diode 8 from an additional DC power supply 9 (AC / DC converter), in which the power of the thermoelectric heat pump is controlled by the control unit 10 by pulsed gravel DC modulation that flows through the thermocouples.

The thermoelectric heat pump utilizes the Peltier effect of the thermoelectric cells 1 in parallel in parallel so that the maximum power of the electrofoil panel 6 corresponds to a 75% 90% load on the thermoelectric cells 1.

Industrial usability

The essence of the technical solution is that this device belongs to the group of renewable energy sources. It uses primarily solar energy and ambient temperature to meet the need for cooling or heating, where the use of the prior art unnecessarily increases the cost of input, operating costs, and the consumption of reactive energy from the distribution network. it is necessary to use DC / AC converters where the mains losses of electricity and therefore long to no return on investment. Since the electro-photovoltaic collectors do not have a stable output, they cannot be practically used as a separate power supply for heat pumps with an electric motor for the compressor.

This technical solution does not need a direct connection to the distribution grid, therefore its use has the advantage of reducing the costs associated with the construction of utilities.

The thermoelectric heat pump has minimal dimensions, low operating costs, less noise and consists of fewer parts, which predetermines its long service life due to the lower number of parts used.

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List of reference marks (1) - tetmoelectric element (2) - interior heat exchanger no. 1 - bottom (2a) - interior heat exchanger no. 1 - top (3) - interior heat exchanger no. 2 - bottom (3 a) - interior heat exchanger no. 2 - top (4) - mounting mechanism (5) - thermal insulation (6) - electro-lithium panel (7) - electric accumulator (8) - separation diode (9) - mains DC power supply (10) - foundation unit (11) - tetmoelectric unit (12) - cold water heat exchanger (13) - hot water cooler (14) - buffer tank

Claims (4)

PROTECTION REQUIREMENTS 3. Thermoelectric heat pump, characterized by the fact that for heating / cooling the water in the accumulation vessel and in the floor, wall or ceiling heating / inspection pipes, 5 is a series-parallel connection of thermoelectric cells (1) based on the Peltier effect directly to the electro-electric panels (δ). The thermoelectric heat pump according to claim 1, characterized in that it uses two types of indoor heat exchangers: circulating and continuous. A thermoelectric heat pump according to claim 1, characterized in that it uses two 10 types of outdoor heat exchanger: a cold-water heat exchanger (12) on a solar-oriented south-facing world sulfur and a hot-water cooler (13). in the shade away from the sun's rays on the north-facing world side of the object. Thermoelectric heat pump according to claim 1, characterized in that the thermoelectric cells (1) are directly connected to the electropotovoltaic panels (6). The thermoelectric heat pump according to claim 1, characterized in that it comprises an electric accumulator (7).