NL1009011C1 - Domestic heating system uses energy derived from environment of dwelling - utilises three stages of heat pump circuits between roof top energy collector panel and domestic heating system - Google Patents

Abstract

The energy collector on the roof is a hybrid type which has photovoltaic cells and a pumped low temperature water or air circuit. The low temperature circuit is coupled to a secondary heat pump circuit via a buffer heat exchanger. A tertiary heat pump system and heat exchanger then supplies hot tap water at up to 65 [deg]C. It also supplies heated water or air at 38 [deg]C. to an underfloor heating system.

Description

Device for extracting energy (thermal and electrical) from the environment and using this energy for the energy supply of a house.

The invention relates to a device for extracting energy from the environment and making it usable for the entire energy supply of a house or building. The energy recovered has a thermal and an electrical character. Figure 1 shows the elements of the system and their interrelationship and cooperation, respectively.

The first element (going from left to right in Figure 1) of the energy recovery device is a hybrid energy collector. Figure 2 shows a cross section of this collector, which is built up from different layers, each with a specific function. The functions of these layers are discussed from 'outside in'. Existing Photo Voltaic cells convert part of the radiated solar energy into electrical energy. Placing these cells on a roof of a house or building in, so-called 15 PV panels, will capture more solar energy in proportion to the size and number of the PV panels and proportional to the cell efficiency, for example 15 %, partly converted into electric direct current. Each PV panel is combined with a second panel that takes care of the absorption of thermal energy. The second panel is mounted on the underside of the PV panel, seen from the sunny side, in such a way (eg glued) that a very good heat conduction to the medium, which absorbs the thermal energy, is guaranteed. This second panel contains channels that flow through a medium. This medium is able to absorb heat or cold (thermal energy) from the PV panel and from the immediate environment. The amount of thermal energy absorbed in the PV panel is equal to the irradiated solar energy, which is not converted into electrical energy by the PV cells, for example about 85%, and the balance of the heat exchange of the combined panel with the immediate vicinity. The latter heat exchange is done by convection, radiation and conduction. There is an air cavity between the second (underlying) panel and the insulated roof. The second panel absorbs thermal energy from the environment via this cavity. This energy is transported to the panel by radiation from the roof and convection of the air flowing past.

30

The second element of the device is the medium circulating with the aid of, in principle, a circulation pump. As an example in figure 1 the ambient temperature is set at 5 oC. The temperature of the supplied medium is set at 0 oC, the temperature at discharge 4 oC. The same medium that has absorbed the thermal energy transfers this heat or cold via a circulation to a heat exchanger.

1 00901 1Ί 2

This heat exchanger in turn delivers the thermal energy to a storage tank for storing this energy or directly to a heat pump circuit (WP1). This is the third element of the device. In either case, storage or heat exchanger, this supply of thermal energy functions as an energy source for the first heat pump circuit. This source will usually have a temperature below the ambient temperature level. In the storage vessel of figure 1, which, due to the low temperature, needs little or no insulation, a temperature of -2 oC prevails. The medium in the storage vessel has a layered temperature build-up.

The heat pump circuit with WP1 is the fourth element of the device. This circuit transports the thermal energy absorbed from the lower temperature energy source (storage vessel or heat exchanger) to a higher temperature level together with the energy supplied to the drive heat pump. Existing systems can be used with media that are customary for the temperature range.

The fifth element is a storage vessel for the storage of thermal energy. The heat pump delivers the thermal energy to this storage vessel via a heat exchanger. The medium in the storage vessel has a layered temperature build-up. Alternatively, the heat can be transferred directly to another medium, usually water, for the space heating and / or the domestic hot water supply of a house. In the example of figure 1, the temperature in the storage vessel is set at 40 ° C.

The sixth element is the heat delivery system for the space heating of the house or building. In order to keep the temperature level of the heat output low, a so-called low temperature heating system is preferably used. This can be floor and / or wall heating. In the example of figure 1, the supply temperature of the water to the rooms to be heated is 38 oC and the return temperature 33 oC. These systems are normally commercially available. This heating system absorbs the heat with the water from the storage tank or indirectly via a heat exchanger.

30 The seventh element is a second heat pump circuit (WP2). If the temperature in the second storage vessel is not high enough, a second temperature increase may be required for the hot tap water supply. In the example of figure 1 from 40 to 65 oC. A second WP2 heat pump can be used for this. This second heat pump WP2 absorbs the required thermal energy from the higher temperature storage (40 oC) or via the higher temperature heat exchanger of the first heat pump circuit with WP1 and delivers that energy at the desired temperature level (approx. 65 oC) of the hot tap water supply.

^ 0090 ίIn 3

The function of the storage vessels for the storage of the thermal energy at the lower and higher temperature level is to equalize the disparity in supply and the need for space heating and hot tap water. At night no solar radiation will be able to provide the energy supply. energy is needed for example: heating, ventilation etc.

5

The second function of the panel, which absorbs thermal energy from the environment and is placed under the PV panel, is to ensure that the temperature of the PV panel does not rise by direct summer solar radiation so that the conversion efficiency of the PV cells go down unacceptably.

10. Example

The following information applies to a concrete house design: 15 Heated floor area 138 m2 Loss area 342 m2 EPC 0.8

Maximum heat requirement 5.3 kW

Annual heat requirement 4660 kWh (RV) and 1909 kWh (TV) 20 Electricity requirement 3791 kWh

Heat pump 2.5 kW thermal

Coverage WP-sun 69 to 90% (depending on the concept) PV energy roof 40 m2

Coverage ratio PV 96.3% 1 009 011

Claims (2)

1. Device for extracting energy (thermal and electrical) from the environment and using this energy for the energy supply of a house. The device consists of seven cooperating operational units, successively: hybrid energy collector, a circuit 5 in which a medium transports thermal energy, storage vessel or heat exchanger for the transfer of the thermal energy, a first heat pump circuit (WP1) that absorbs the thermal energy and in temperature increases, storage vessel or heat exchanger that takes the thermal energy from WP1, a space heating circuit that takes thermal energy from the higher temperature storage vessel and releases it for space heating, and a second heat pump 10 circuit (WP2) that takes heat from the higher temperature storage vessel and in temperature increases for domestic hot water heating. 2. The hybrid energy collector, consisting of a PV panel with PV cells, which converts collected solar radiation into electrical energy and a panel mounted underneath, with which thermal energy from the PV panel and the environment is absorbed and passed on to a transport medium. for thermal energy. The characteristic of the composite panel is that there is very good heat conduction from the PV panel to the thermal energy transport medium. 1 00901 1-i