LT2010041A - Heating and cooling system - Google Patents

Abstract

The invention relates to thermal techniques, specifically for room heating and cooling systems. By different devices is absorbed renewable solar radiation, wind pressure and water energy gives different result. Solar energy produces heat, cold and electricity. Open wind pressure through impeller generates rotary energy, which turns the fan and produces closed air pressure in ducts, spins water pump and lifts water into higher cascade, spins compressor of heat pump and retains heat in the heating ventilating system also removes polluted air, spins electric power generator and produces electricity. The water collected in higher cascade it's potential energy gives when the water is falling down through filters in the water purification system; and turns the turbines which generates electricity. This whole process is a renewable energy source differentiation by the devices, for achieving different even opposite effect.

Description

1

The invention, the heating-ventilation system, belongs to the energy and thermal engineering, specifically belongs to the heating and ventilation of premises, the production of hot water and steam, by absorbing, storing, storing and using solar and water energy, it is the elements of 5 renewable energy heating system. , solar-energy multi-level panels, solar-powered, and heat-retaining one or two transparent partition structures for water and heat storage pumps and thermal insulation thermal insulation.

Technical level. Renewable sources include inventions known in the patent literature 10 DE19544245, JP2000073594, when solar heat used for space heating, falling on the surface of building membranes, is distributed internally. Another closer to the proposed invention is the USSR patent no. 996696 describes a heating system comprising vertical greenhouses and a ventilation system connecting the building. The prototype can be considered as a heating system as described in EN 2007 023, consisting of several solar-absorbing groups, where each of the 15 other groups uses an increasingly high temperature heat carrier and a solar beam concentration on the energy absorbing plates, which is the closest to the proposed invention. The drawback of the known and other known inventions here is the one-sided accumulation of solar energy, even the isolation of thermal insulation and insufficient heat preservation on both the shade and the illuminated side of the building, the insufficient capacity of the batteries and the narrow profile of their use, limiting the use of the invention when there are higher time intervals without sunlight low outside temperature. All these shortcomings have been removed in the proposed heating / ventilation system.

The essence and novelty. The essence and novelty of the heating-ventilation system consists of the heating ventilation devices used in the system for achieving different heating and ventilation goals; In order to achieve greater energy reception and preservation, the building partitions are equipped not only with 25 transparent but also repetitive, oppositely oriented parts, with high-resistance thermal insulation, which is equipped with cold storage devices; parts of the building are thermally insulated with solar-coated, low thermal resistance, coated with solar-absorbing materials or through solar channels with solar-absorbing panels, over which one or more transparent partitions are provided through the ducts; the channel, the first and second transparent partitions 2 form a gap-channel, all the openings covered by the additional enclosure, the solar-thermal insulation of the building parts, the solar-absorbing panels and the transparent partitions have different thermal and insulation resistance, which is higher in the upper part of the building; a dark-colored paint layer on the walls of the building, with dark colors in the space; figured plastic plate with 5 protrusions towards the wall, goffic vertical - metal plate and volumetric metal plate filled with heat carrier, transparent partitions secured in space; plastic packages, double-glazed units, two-chamber glass packs and lenses, the space between the solar-absorbing panels and the walls of the building is limited vertically by low-supporting belts, corners of the building and the edges of the holes with figurative strips, the beginning of the canal is at the bottom of the building 10, in the clean air well, and the end at the top of the air distribution manifold via air conditioning software controlled valves connected to air supply ducts or a heat pump directly connected to the bath and shower ventilation, and the heat pump connected to the deflector or deflector through the air heat exchanger with a ventilation manifold and ventilation ducts, clean, heated air and water collectors are installed on the perimeter of the building at the perimeter of the building, connected to the heating, and in the shaded area the coolers and collectors connected to the ventilation are cleaned on the ground. , heated solar energy, air well, and high-resistance thermal insulation in the shaded area, long heat pipes absorbing cold energy, type of liquefied gas filled with liquefied liquefied gas, 20 slanted in a shade-mounted fridge with heat exchanger filled with low temperature energy carrier connected by means of circulating tubes directly or via compressor with freezer cold energy transfer heat exchangers and either through the valves of the air conditioning system with ventilation air ducts, the heat and water bottom collector is located in the lowest part of the building, clean heated water and 25 air collectors in the building plinth, vertical heat -Water heater in heated air well between cap and shelter, top water-heat accumulator; covering liquid heat carrier, floor pipes and radiators in rooms for heating, hot water and steam in the shelter, on the internal capital wall, the upper collector is located outside the building, heat exchangers are installed inside all heat storage units, interconnected through the valves controlled by the air conditioning program 30. 3

Panels and panels therefor mounted on a sun-lit surface; the thermal resistance of the carcass, building walls and roofs, according to the absorption and temperature resistance, are different, are connected to each other by circulating pipes, with radiators and accumulators of the heating system, heat and water accumulators are installed on several levels according to altitude and 5 temperature, thermal insulation of the passive house equipped with a shade of a shadow building, and in addition to the cold accumulator, heat exchangers filled with energy carrier and connected to the circulating tubes directly with the air heat exchangers, via a compressor with a freezer or ventilation heat exchanger, attached to a cap as a solar absorbent plate, dark-colored stamped rolled plastic panel {stamped with 10 bumps towards the wall, above - a metal dark colored vertical corrugated plate attached to a wall or frame, even above - illuminated by walls or roofs tertiary, third level - volumetric, radio-type, vertical dark-colored metal plates fixed like the first, filled, heat carrier, interconnected and or grouped and circulated with the accumulator-15 heat exchanger-coils, in addition to solar-absorbing panels mounted in sun-lit building areas on a frame, wall or roof structure such that naturally between the frame thermal insulation, walls, roofs, strips on one side and heat-absorbing plates on the other side form vertical broadband ventilation ducts, fed under fresh air at the bottom through the extended inverted funnel In the form of a collector with 20 grilles, a drainage duct and an air filter, the top air ducts at the top end up with a manifold connected to the heating ducts inside the heated rooms, according to the building's lighting section. Water-collector and battery-pool are installed on the perimeter of the s-part, while the cold-storage accumulator, the transparent barrier structure above the first-level solar-absorbing panels are framed or framed by 25 transparent plastic packages, framed by transparent transparent panels above the second level of solar energy. chamber glass packs, also used for shutters, and above level three - single or double chamber glass units, with a beam of concentrating light above the highest energy level solar panels, transparent brackets. thermo-insulated boards, equipped with a second transparent partition on the illuminated side of the building from the ground up to the roof and over the roof forming a fresh 4-heated air broadband one of the different devices using solar energy filled with liquefied and lightly vaporized gas, a tubular balloon built in a small angle vertical, accumulates cold, another different device is on the frame and either a separate support is fitted with a turbine, uses wind instead of generating electricity and or 5 axial rotation energy, accumulating water in the upper basin and or heat in the heat exchanger, some of the transparent partition structures used to generate the photovoltaic, in addition to the altitude; The lower battery-pool is located below the basement floor, although in a low but positive temperature in a strong contact environment, so its thermal capacity is much higher than a simple total, the collector at the level of the cap - stretched over the entire building 10, sun-oriented, perimeter, underground, as in the shadow, the building is protected by high thermal insulation, and in the ground, the transparent battery is installed between the underground part and the shelter, the top battery installed in the shelter, the upper battery pool outside the building, all the batteries through the heat exchanger circulating pipes is connected by 15 to each other and to energy users, by the temperature of the upper battery the pool is the largest volume of the ambient temperature artificial or natural water source connected to the circulation pipes by v. andens with a water temperature higher than the outside temperature and its water in the pipe or in the cascade of falling water cascade complement the volume of the lower battery pool, so it is also called 20 cascade, connected by circulating tubes, the heat transferred by the heat carrier from the upper-highest temperature and the vertical - for medium temperature batteries, the top battery consists of three levels; The heat exchanger is connected to the heat exchanger using a concentrated mass of solar radiation, the heat exchanger is connected to the DHW circuit, the heat exchanger is connected with 25 circulating pipes and the heat exchanger of the underfloor heating system is connected to the lower pipe. level boards; each level is formed by heat transfer coils-heat exchangers connected to concentrated solar panels - steam, panels of volumetric plates - hot water and dark panels or their 30 groups - energy carrier of the heating system, connected by circulating pipes to indoor heating radiators, in addition to baths and shower drainage, toilets and other indoor ventilation 5 are connected to a heat pump, which on the other hand is connected to the circulation pipes by heat exchangers, finite pipes with drainage and a deflector of contaminated air, or the first cold air, which is obtained by separating the heat pump with the heat pump The ventilation structure exchanger, the collector with the ventilation ducts, where the cold air flows down to the 5 ventilated rooms, the building part of the building is equipped with a multi-layered and multilayered structure; flowing up-air barrier, solar-absorbing panels, second flowing up-air curtain, transparent frameless clear plastic or glass enclosure, fresh air well and glass packs fixed to the frame, wall or roof-extended supports and openwork or glass-aluminum 10 overlays for each floor connected by a staircase leading up to a vertical battery.

Description of the drawings.

Fig. 1 is a cross-sectional view of the home heating-ventilation scheme in section A-A.

FIG. Fig. 15, detail section B-B.

Fig. 4, detail section C-C.

Fig. 5, detail section D-D.

Fig.6, detail section E-E. The heating and ventilation system is designed for heating buildings and structures and ventilating with renewable energies; In the process of receiving, storing, distributing and saving heat, it consists of a building, air and solar energy absorbing equipment, thermal insulation layers, pumps, fluid and air transfer channels, and carriers, heat exchangers, energy storage, and parts of the building that are oriented towards the sun. Resistance Thermal Insulation, Surface Covered with Solar Absorbing Materials or Over-Spacer 1 Solar Absorbent Panels, One or More Transparent Enclosures Fixed on Spacer 2 Fasteners, All Slots Oriented to Part of Building and Opposite Surface Coated 3 while the shaded part is covered with high thermal resistance thermal insulation 4, solar panels, solar panels and transparent partitions, and thermal insulation, selected with different thermal and insulation resistance, which higher in the upper part of the building; dark color paint on the walls of the building, attached in dark color; figured bumps towards the wall stamped plastic plate 5, corrugated vertical - metal plate 6 and volumetric type, metal plate 7, filled with heat carrier, circulating tubes 35 connected to heat exchanger 5, mounted in upper heat storage 34, formed through channel 1 and 2 vertically fixed support bands 12, angled bands 13, angled strips 14 are provided with transparent brackets; Plastic Packages 8 - Lowest, Glass Packages 9-Top, Two-chamber Glass Packages - Highest, especially where the temperature of the sun-heated air is the highest and the sun-concentrating lenses 10, installed above the 10 heat-insulated and roof-mounted energy-absorbing panels 11, each channel The start is installed at the bottom of the building, at the level of the plinth in a clean air collector 15, and the end at the top of the warm air distribution manifold 16 via the air conditioning control valves connected to the air inlet ducts 17, these channels should be provided with circulating fans, because the warm air to be directed downwards, but the 15 most important fans of the air conditioning program have the advantage of differentiating each room's heating, and either the collector 16 is connected to a heat pump 18 directly connected to the bath, shower ventilation. channel 19 and deflector 20, the air from which the separated heat passes through the heat exchanger 21 and cools downward air to the ventilation manifold 22 connected to the ventilation ducts 23, clean water collector 24 arranged in the underground part of the building at the perimeter 20 of the building, in the ground part of the building the perimeter, orthogonal to the sun, is equipped with a clean, sun-heated, air well 25, and the shadow section is equipped with a cold storage 26, with heat exchangers 27 cooling the upstream air to the ventilation ducts 28, the heat accumulator itself consists of a water tank 29, a heat pipe 30 accumulating cold from the environment to not only 25 containers 29, but also to the ground, large arrays, while the outside temperature is much below zero, all the openings of the building are equipped with swinging shutters and punctures attached to the eyebolts 14 of the glass packets 9 , heat and water The lower storage unit 32 is located in the lowest part of the building, the vertical heat-water heater 33 is located in the heated air well 25 between the cap and the shelter, the air well from the environment 30 is protected by a transparent bracket 36 connected to the building-extended supports 37 and the openings 38, the upper water- heat accumulator 34; covering liquid heat carrier 7, floor heating pipes and radiators indoors, hot water and steam in the shelter on the internal capital wall, the upper collector is located outside the building, heat exchangers 27 inside all heat storage units are connected, circulating pipes 35 are connected to each other and operation is controlled by valves connected to 5 air conditioning software. The operation of the heating-ventilation system is based on the total heat resistance of the walls, thermal insulation and other partition structures of the partitioning structures, which is optimized, which reduces the heat loss, and the gap-channel 1 between the solar-absorbing panels and the building walls does not only act as an air-insulating layer. but as the warmer air, with the warmth of the self-contained inside of the building and solar-absorbing panels, the enclosure curtain, which returns heat to the re-heating of the indoor premises, as the heating-ventilation system is installed around the entire perimeter of the building, starting in the sun and ends in a shelter, it is basically a broadband dual ventilation duct that operates due to the absorption of solar energy in plastic plates 5, metal plates 6 and 15 in volumetric, radiator shape, slabs 7 and inlet spaces 1 and 2, which heating upwards, the higher, the more heated, the warm air collector 16 is filled, it is distributed to the space heating ducts 17 or the heat is concentrated in the heat pump 18 to the heat storers in a row; to the upper heat storage 36, the volumetric heat exchanger 39, and finally to the heat and water lower storage 32, 20 where the accumulation of excess heat is greatest due to its massiveness and contact with the entire underground part of the building, so during the summer heat and sunny days, the lower storage can accumulate all excess heat energy, accumulated energy allows for normal heating for much longer periods of time when the lowest temperature, the shortest sunny day time and the low number of sunny days, in the case of cloudiness, the second transparent partition 25 36 is installed; the air collector 16 and the water collector 15 mounted at the level of the two transparent partitions, the air well 25, which reaches heat loss and solar energy, is heated with fresh and clean air and water, thereby reducing the temperature difference at each wall of the building closer to the building; this reduces total heat loss, shutters and punctures significantly reduces heat losses through openings, eliminating 30 heat losses, eliminating dirty, polluted, exhausted air, and optimizing the temperature in this system by connecting bath and shower ventilation ducts 19 with 8 heat pumps and exhaust air removal through the deflector 20, and the cold box 26 of the building, consisting of a water tank 29 and a heat pipe 30 with a heat exchanger 27 filled with a low temperature heat carrier and circulating tubes 35 connected directly or via a compressor with ventilation air ducts 31 cools the interior 5 air-conditioning facilities. The heating-ventilation system includes the above-mentioned and non-listed uses, but in the definition, especially when choosing cheaper combinations now that price relationships are distorted and climate and tax change unpredictable, this invention can provide energy independence and comfort, affect the balance of energy raw materials and energy. commodity prices and other commodity prices of 10 energy commodities will also balance, including environmental pollution and public relations. 15 20

Claims (1)

9 DEFINITION 1. The heating / ventilation system consists of a building, solar energy absorbing equipment, thermal insulation layers, pumps, liquid and air ducts, energy carriers, heat exchangers, energy storage devices, characterized in that the building parts are oriented to the sun 5 with weak thermal insulation, which the surface is covered with solar-absorbing materials or solar-energy-absorbing panels, over which one or more transparent partitions are fixed through the gaps; a canal (1) between the plate and the wall, a channel (2) between the plate and the transparent partition, all the openings are provided with an additional enclosure (3), and the thermal side of the building is covered with high thermal resistance 10 (4), 2. Heating-ventilation A system according to claim 1, characterized in that, on the building parts, solar-oriented solar energy absorbing panels, transparent partitions and thermal insulation are selected having different thermal and insulation resistance, which is higher in the upper part of the building; covered with a dark coat of paint on the walls of the building, dark colors over 15 gaps (1); figured bumps towards the wall stamped plastic plate (5), above, goffer vertically - metal plate (6) and above - volumetric type, radial type, metal plate (7) filled with 'heat carrier, spaced through gaps (2) transparent partitions; plastic packages (8), double-glazed units (9), double-chamber glazing units and lenses (10) installed above insulation and roof-mounted energy absorbing boards 20 (11) 3. Heating and ventilation system according to claims 1 and 2, characterized in that the width and thickness of the gaps (1) and (2) are limited by the vertically attached support strips (12), the corner strips (13), the ribbing strips (14), the start of the channels at the bottom of the building, the collector (15) at the level of the cap in the clean air well and, at the top, a warm air distribution manifold (16) connected to air supply ducts (17) and / or a heat pump (18) to which bath and shower ventilation ducts (19) and deflector (20) are directly connected; ventilation heat exchanger (21), ventilation manifold (22) and ventilation ducts (23). 4. A heating / ventilation system according to claims 1, 2, 3, characterized in that, according to the perimeter of the building, a solar collector (24) of clean heated water is installed in the underground part of the sun, and an air well (25) formed in the ground by transparent partitions (36). in the shadow section, a cold storage device (26) is provided, connected to the ventilation ducts (23) and (31) via heat exchangers (21) and (27). 5. A heating / ventilation system according to claims 1 to 4, characterized in that the cold energy storage device (26) is provided with a water tank (29) and a heat pipe (30), in the form of long liquefied gas cylinders, filled with easily evaporated, liquefied gas, leaning to the frost-mounted freezer. 6. Heating and ventilation system according to claims 1 to 5, characterized in that the heat and water bottom collector (32) is located in the lowest part of the building, the clean heated water and air collectors in the building part of the building, the vertical heat-water heater (39) being heated by the air. in the well between the cap and the shelter, the upper water-heat accumulator (34); covering liquid heat carrier, floor pipes and radiators in rooms for heating, hot water and steam storage, installed in a shelter, the top collector is located outside the building, heat exchangers inside all heat storage units are interconnected by circulating pipes (35) through the air conditioning controlled valves.