LT5827B - 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

The invention relates to heating and ventilation system, which relates to energy and thermal technology, specifically to heating and ventilation of premises, production of hot water and steam, absorbing, storing, storing and utilizing solar and hydro power, elements of renewable energy heating system, level panels, solar powered, and heat retaining one or two transparent enclosure / water and heat storage pumps and heat retaining thermal insulation.

State of the art. Renewable sources include the inventions DE19544245, JP2000073594, known from the patent literature, where solar heat falling on the surface of building membranes is used for indoor heating. Another closer to the present invention is the USSR patent no. 996696 describes a heating system comprising vertical greenhouses and a ventilation system connecting to a building. A prototype heating system described in EN 2007 023 may be considered to consist of a plurality of solar-absorbing groups wherein each of the other groups utilizes an increasingly high-temperature heat carrier and a concentration of solar radiation on the energy-absorbing panels, the closest to the present invention. The disadvantages of the other inventions noted herein are the one-sided accumulation of solar energy, even the isolation and thermal retention of both the shaded and illuminated side of the building, the inadequate capacity of the batteries and their narrow profile. outside temperatures. All shortcomings in the proposed heater-ventilation system have been remedied.

Essence and novelty. The essence and novelty of the HVAC system consists of the HVAC units used in the HVAC system for different heating and ventilation purposes; in order to increase energy absorption and storage, the solar-facing partitions of the building are equipped not only with transparent, but also with repetitive, opposite-oriented parts, with high-resistance thermal insulation with cold accumulators; the parts of the building are oriented towards the sun with low thermal resistance with a heat-insulating surface or covered with solar-absorbing materials or with interconnecting panels with one or more transparent barriers, the first partition and thermal insulation forming an interconnection the first and second transparent enclosures form a gap-duct, all openings are covered by an additional enclosure, solar thermal panels, solar-absorbing panels and transparent enclosures have different thermal and insulating resistance, which is higher in the upper part of the building; a dark coat of paint on the walls of the building with a dark coat applied between them; a plastic plate stamped with figurative protrusions towards the wall, a metal plate and a volumetric metal plate filled with a heat carrier, and a transparent barrier fixed in the space; plastic packets, glazing units, dual-chamber glazing units and lenses, the space between the solar panels and the walls of the building is limited by vertically low support bands, corners of the building and the edges of the openings are shaped bands, the channel starts at the bottom , in the air distribution manifold, through dampers controlled by the air conditioning software, connected to ducts or heat pump directly connected to the bath and shower ventilation, and the heat pump connected to the deflector or to the deflector through the ventilation heat exchanger to the ventilation manifold, and ventilation ducts, solar heated underground perimeter of the building installed in the underground clean air and water collectors connected to heating, while in the shadow part of the building, cold collectors and collectors connected to ventilation, the ground heated solar power, air well, high-resistance thermal insulation in the shade, long heat pipes absorbing cold energy, liquid gas type, filled with easily evaporated liquefied gas, leaning on a shaded cold storage tank with heat exchanger, low temperature energy carrier and circulator connected directly or via a compressor to the heat exchangers of the freezer cold energy transfer and or via dampers of the software conditioning system with air supply ducts of the ventilation system, the lower heat and water accumulator in the lower part of the building, the clean heated water and air collectors in the heated air well between the plinth and the shelter, the upper water-heat accumulator; comprising a liquid heat carrier, floor heating pipes and radiators for space heating, hot water and steam installed in a shelter, on an internal wall, upstairs storage outside the building, heat exchangers installed inside all heat storage units interconnected through valves controlled by the air conditioning program.

Panels and groups thereof mounted on sunlight; frame, building walls and roofs are different in terms of absorption and temperature resistance, thermal resistance, circulating pipes are connected to each other, radiators and batteries for heating system, heat and water batteries are installed in several levels according to altitude and temperature, a heat transfer plate filled with a heat exchanger and filled with heat transfer heat exchanger, filled with energy carrier and circulation pipes, directly connected to ventilation heat exchangers, through a compressor with a freezer or ventilation heat exchanger, a dark colored rolled plastic plate attached to the cap as a solar absorbent plate , with tensioned protrusions towards the wall, above - a metal dark-colored vertical corrugated panel fixed to a wall or frame, and above - in a wall or roof under sunlight in sheets, the third level - volumetric, radiator type, vertical dark metal plates, mounted like the first, filled with heat carrier, connected to each other and / or connected to groups and circulation pipes with accumulator-battery heat exchangers-coils, in addition to solar energy-absorbing plates mounted in sunlighted areas of the building to the frame, wall or roof structure such that, naturally between the frame's thermal insulation, wall, roof, strips on one side and heat-absorbing panels on the other, form vertical wide-band ventilation ducts fed by fresh air through an extended inverted funnel equipped with grille, condensate drainage duct and air filter, at the top the broadband ventilation ducts terminate in a manifold connected to the heating ducts open inside the heated rooms, according to the lighting part of the building. erimeter water collector and battery25 pool, and shadow with cold accumulator, transparent enclosure structures above first level solar panels, framed or frameless transparent plastic packs, above second level solar panels, framed transparent single-chamber glass panes, which are also used to form shutters, and above the third level are single or dual-chambered panes of glass, concentrating a beam of light above the highest energy-absorbing solar panels, transparent partitioning structures on the roof or panels mounted on the roof dome on the thermal insulation; equipped with a second transparent partition structure on the illuminated side of the building, from the ground to the roof and above the roof, forms a broadband well of heated heated air, one different devices using solar energy are filled with liquefied and easily evaporated gas in a tubular type cylinder, placed at a slight angle from the vertical, accumulates cold, another different device is on the frame and or on a separate support turbine, uses wind and generates electricity and or axial rotation , accumulates water in the upper basin and / or heat in the heat accumulator, part of the transparent enclosure structure is used to generate photovoltaic, in addition to altitude; the lower accumulator pool is located below the basement floor, albeit at a low but positive temperature in a strong contact environment, so its thermal capacity is much higher than a simple total, the cap at basement level extended to the entire building, facing the sun, perimeter, underground and in the shade, the building is protected by high thermal insulation and the ground part has a transparent barrier, a vertical battery installed between the underground and the shelter, the upper battery installed in the shelter, the higher battery pool outside the building, all batteries through energy transfer heat exchangers are interconnected and with energy users, the temperature-dependent pool is the highest volume, ambient temperature artificial or natural source of water connected to the water by circulating pipes a collector with a water temperature higher than the outside temperature and its water or amusement cascade to add volume to the lower pool basin, which is also called cascade, circulating pipe, heat carrier excess heat from upper-to-upper temperature and vertical to medium temperature accumulator, upper battery consisting of three levels; the upper steam generator, its heat exchanger is connected to the circulation heat exchanger using concentrated mass of solar radiation, the middle to hot water production, the heat exchanger is connected to the high-level volume plates by the circulating pipes and the lower heating system service heat exchanger is connected to the lower level plate ; each level is formed by heat transfer coils-heat exchangers connected to concentrated solar receiving panels - steam, volumetric panels - hot water and dark panels or groups thereof - heating system energy carrier, connected via circulators to space heating radiators, shower drains, toilets and other indoor ventilation are connected to a heat pump, which on the other hand is connected to heat exchangers by means of circulation pipes, exhaust pipes and a deflector for the removal of contaminated air or first cold air produced by heat heat separation through the ventilation heat exchanger, a multi-layered and multi-layered envelope structure of the solar-oriented part of the collector with ventilation ducts, where the cold air flows down to the ventilated premises; flowing uphill air barrier, solar panels, second flare uphill air curtain, transparent frameless clear plastic or glass barrier, fresh air well and glazing mounted on frame, wall or roof with extended supports and openwork or glass-aluminum underlay each floor connected by a vertical staircase.

Description of the drawings.

Fig. 1 is a general view of the house heating and ventilation scheme in section A-A.

Fig.2, Basement plan of the house scheme.

Fig. 3, section B-B of the detail.

Fig. 4, a sectional view C-C.

Fig. 5 is a sectional view taken along the line D-D.

Fig. 6, a sectional view E-E of the detail.

The HVAC system is designed to heat and ventilate buildings and structures using renewable energy; receiving, storing, distributing and saving heat and therefore consisting of a building, air and solar absorbers, thermal insulation layers, pumps, fluid and air transfer ducts, and carriers, heat exchangers, energy storage devices, the building's solar-oriented resistive thermal insulation with a surface covered with solar-absorbing materials or with solar-absorbing panels above the interconnector 1, one or more transparent enclosures fixed by latches above the interconnector 2, all openings facing the sun in the building and opposed by an additional enclosure 3, and the shaded part is covered with high thermal resistance 4, solar panels and transparent enclosures attached to the sun-oriented parts of the building and selected with different thermal and insulating strengths from the upper part of the building; a dark coat of paint on the walls of the building attached to a dark color; molded projections towards the wall plastic plate 5, corrugated vertically metal plate 6 and volumetric radiator type metal plate 7 filled with heat carrier circulating pipes 35 connected to a heat exchanger arranged in the upper heat accumulator 34 formed vertically by passages 1 and 2 transparent enclosures with support strips 12, corner strips 13, angled strips 14; plastic packs 8 - lowest, glazing 9 10 above, dual-chamber glazing - highest, namely where the temperature of the solar heated air is highest and the sun-focusing lenses 10, placed above the energy-absorbing panels 11 on the insulation and roof, installed in a clean air manifold 15 at the bottom of the building and a hot air distribution manifold 16 at the top, via dampers controlled by air conditioning software, connected to the ducts 17, it is expedient to provide these ducts with circulation fans, downwards, but the main advantage of the fans controlled by the air conditioning program is to differentiate the heating of each room and either the collector 16 is connected to the heat pump 18 to which the baths, shower ventilation ducts are directly connected a cavity 19 and a deflector 20, the air from which the separated heat passes through the heat exchanger 21 and cools the downstream air to the ventilation manifold 22 connected to the ventilation ducts 23, a clean water collector 24 located under the perimeter of the building sun-facing, equipped with a clean, solar-heated, air well 25, and a shaded chiller 26, with heat exchangers 27 to cool the upstream air into ventilation ducts 28, the heater itself consisting of a water tank 29 and heat pipes 30 accumulating cold from the environment not only to the container 29, but also to the ground in large arrays, at a time when the outside temperature is well below zero, all openings in the building are equipped with hinged shutters and hinges hinged to angled strips 14 of glazing 9 and water to lower a manifold 32 is located in the lowest part of the building, a vertical heat-water accumulator 33 is provided in a preheated air well 25 between the plinth and the shelter, the air manhole is protected from the environment by a transparent enclosure 36 connected to the building with extended supports 37 34; comprising a liquid heat carrier, floor heating pipes and radiators for space heating, hot water and steam, sheltered on an internal capital wall, high-rise storage outside the building, heat exchangers 27 installed inside all heat storage, interconnected by ducts 35 with air conditioning software.

The basis of functioning of the heating and ventilation system is the total heat resistance of the partition walls, thermal insulation and other partition structures, its optimization which reduces heat loss, and here the gap-duct 1 between the solar panels and the building walls does not only act as an air insulation layer. but also as a partition curtain for warmer air that takes in the heat of the panels passing through the interior of the building and absorbs solar energy, since the heating-ventilation is located along the entire perimeter of the building facing the sun, ends in a shelter, which is basically a broadband dual ventilation duct that works by absorbing solar energy in the plastic panels 5, metal panels 6 and volumetric, radiator-shaped panels 7 and in the delivery spaces 1 and 2 for heated air s rising up, the higher the warmer it fills the hot air collector 16, distributing it for space heating to the ducts 17, or transferring the heat concentrated through the heat pump 18 to the heat accumulators in sequence; to the upper heat accumulator 36, the vertical heat accumulator 39 and finally to the lower heat and water accumulator 32, where the accumulation of excess heat is greatest due to its bulk and contact with the entire underground building, allowing the lower accumulator to accumulate during the summer heat and sunny days excess heat energy, the stored energy allows normal heating for a significantly longer period of time with the lowest temperatures, shortest days of sunshine and low number of sunny days under cloudy conditions, a second transparent baffle structure 36 is added; heat and hot air and water are heated at the cap-level air collector 16 and the water collector 15, the air collector 25, to heat and fresh air while reducing the temperature difference at each ever closer wall of the building; thus reducing the total heat loss, shutters and sashes significantly reduce heat loss through openings, minimizing heat loss by eliminating contaminated stale air and optimizing temperature is the combination of bath and shower ventilation ducts 19 with heat pump and strain remover 20, and a chill accumulator 26 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 pipes 35 connected directly or via a compressor with ventilation system air ducts 31, conditioning program.

The HVAC system includes the above and non-listed but defined uses, especially when choosing cheaper combinations now that price relationships are distorted and unpredictable climate and tax changes can bring energy independence and comfort, balance the balance between energy raw materials and energy. while commodity prices for other commodities will also be affected, including environmental pollution and public relations.

DEFINITION

Claims (7)

DEFINITION l.The HVAC system consists of a building, solar energy absorbing equipment, thermal insulation layers, pumps, liquid and air transfer ducts, heat exchangers, energy storage units, characterized in that the parts of the building oriented towards the sun 5 thermal insulation having a surface covered with solar energy-absorbing materials or with solar-absorbent panels over which one or more transparent baffles are provided; a channel (1) between the panel and the wall, a channel between the panel and the transparent partition (1) 2) all openings are equipped with an additional enclosure ( 3) and the building's shadow side is covered with high thermal resistance (4), 2. A heating and ventilation system according to claim 1, characterized in that portions of the building oriented towards the sun by solar energy-absorbing panels, transparent partitions and thermal insulation are selected having different thermal and insulating resistance which is higher in the upper part of the building; a dark coat of paint on the walls of the building, a dark color applied through the gaps (1); stamped with figurative bumps towards the wall 15 a plastic plate (5), above, a metal plate (6) vertically in a corrugated form, and above, a volumetric, radiator-like metal plate (7) filled with a heat carrier, transparent passages fixed through the passages (2); plastic packages (8), double-glazed units (9), double-chambered double-glazed units and lenses (10) installed above the insulation and on the roof with energy-absorbing panels (Π) 3. HVAC system according to claims 1 and 2, characterized in that the widths and thicknesses of the passageways (1) and (2) are limited by vertically mounted support strips (12), corner strips (13), angles of edges (14). , the ducts start at the bottom of the building, at the cap level manifold (15) in the clean air well, and at the top at the warm air distribution manifold (16) connected to the ducts (17) and / or the heat pump 25 (18), to which the bath and shower ventilation ducts (19) and the baffle (20) are directly connected and or the ventilation heat exchanger (21), the ventilation manifold (22) and the ventilation ducts (23). 4. A heating and ventilation system according to claim 1, 2, 3, characterized in that in the underground part of the building, a solar heated solar water collector (24) is provided, and in the ground part a well (25) in the shadow is formed by transparent barriers. The unit is provided with a cold accumulator (26) connected to the ventilation ducts (23) and (31) via heat exchangers (21) and (27). 5. The heating-ventilation system according to claims 1-4, characterized in that the cold energy storage device (26) is formed from a water tank (29) and heat pipes (30), 5 cylinders of liquefied gas, filled with easily evaporated, liquefied gas, leaning on a cold storage tank in the shade. 6. The heating system according to claims 1-5, characterized in that the lower heat and water accumulator (32) is located in the lowest part of the building, the clean heated water and air collectors in the base of the building, the vertical heat water water accumulator (39). 10 in the heated air well between the plinth and the shelter, the upper water-heat accumulator (34); comprising a liquid heat carrier, floor heating pipes and radiators for space heating, hot water and steam storage, sheltered, upper storage outside the building, heat exchangers inside all heat storage interconnected by circulating ducts (35) via air conditioning program controlled valves.