RU2526031C2 - Low-rise energy-producing building - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction of low-rise energy-producing buildings, also on permafrost soils, relates to non-conventional power engineering with usage of natural sources of energy and may be used primarily under conditions of moderate and cold climate. The difference is in the fact that when walls are made of wooden elements, logs of smaller diameter are used, starting from 15 cm. In the invention the main elements of the building, such as walls and roof, serve as elements of a wind-solar plant. At the same time the wind generator installed in the building roof starts producing electric energy at wind speed of 0.5-0.8 m/sec.

EFFECT: technical result and substantial differences of a building compared to available ones consist in the fact that a building is a source of electric and thermal energy, is equipped with an anti-precipitation device, wind-gripping vertical partitions placed on external surfaces of the building wall, a solar power plant, solar panels of which are arranged along the entire surface of the flat roof, a plant of atmospheric water supply, a device for air cooling in the building with usage of thermal energy of soil, a plant for automatic removal of snow from the surface of the roof, a device for prevention of ice formation in rainwater pipes and the method of erection of piled footings and operation of low-rise buildings under conditions of permafrost soils.

2 cl, 11 dwg

Description

The invention relates to the field of construction and operation of low-rise energy-saving buildings, relates to alternative energy using natural sources of energy, wind, solar, thermal energy of the soil and can be used in any climatic conditions.

A low-rise energy-saving building is known, including walls made of wooden elements, logs or beams, a roof with awnings, a pitched roof and a solar water heater (R4 940 10773 A1 from 08.20.1996).

The disadvantages of the building are the inability to use the supporting structures of the building, walls, roof, as sources of electrical energy, the difficulty of quickly removing snow from the roof of the building, the large heat loss through the wooden walls and the high cost of electrical and thermal energy.

The proposed solution closest in technical essence is a low-rise energy-generating building (MEZ) with warm wooden walls, acting as a mini-power plant with a capacity of up to 10 kW (patent R4 2421583 from 1 dated June 20, 2011).

The disadvantages of the MEZ are insufficient energy capacity during the flow of air (wind) in the direction of the building’s diagonal, inefficient use of solar energy and atmospheric water supply, low load-bearing capacity of wooden beams, the inability to use small diameter logs and remove ice from drainpipes in the walls, and the building is subject to deformations in case of frost heaving forces and high energy costs when cooling the premises of the building.

A search in the patent and technical literature did not reveal analogues that are close to the claimed invention.

The purpose of the invention is to increase energy efficiency, improve the technical characteristics and economic indicators of the MEZ.

This goal is achieved by the fact that the building is equipped with a compensator of frost heaving forces placed in the ground along the perimeter of the building, vertical partitions located perpendicular to the outer surface of the walls, and wooden beams of increased bearing capacity (PNS). In this case, the compensator is made in the form of an antifreeze layer of clay mortar and placed in contact with the side surface of the building, solar panels are placed on the entire surface of the roof of the building, each wooden wall element is made in the form of half-logs fastened together by adjusting screws, facing convex surfaces to each other, and the heat-insulating expanded material is placed between the half-logs to the entire height of the walls, the PNS beam is made of at least two joined flat vertical wooden elements directly of a carbon shape and equipped with a vertical plate placed between the elements with reversible deformation and high mechanical characteristics, the snow removal unit is made in the form of one central pipe having two rows of side holes facing in opposite directions, and pipes adjacent to one row of holes facing the walls of the building, the air-cooling device is made in the form of an underground collector placed in a shell of clay maximum moistened soil and connected at one end to the air the intake, another with a zone of reduced air pressure in the roof of the building, the atmospheric water supply device is made in the form of communicating heat-insulated tanks half-buried in the ground, which are placed under the drain pipes, equipped with a submersible pump and a water heating element, each drain pipe equipped with a perforated container filled with carbide granules calcium and technical salt and having the possibility of free movement through the pipe, and the fact that during the construction and operation of the building in condition ditions permafrost underground buildings create periodically a gas screen with low negative temperature and the immersion pipe piles are used leader diameter hole two centimeters smaller pile diameter.

The invention is illustrated by the drawing, where in Fig.1,2 in plan and section, in Figs. 3, 4 in plan it is shown a MEZ, in Fig. 5 in section a fragment of a wall of wooden elements is shown, in Figs. 6, 7 in plan and a section shows a PNS beam, Fig. 8 shows a sweep diagram of an atmospheric water supply installation, Fig. 9 shows a subsurface collector in a section, Fig. 10 shows a fragment of a drainpipe in a section, and Fig. 11 shows a pile foundation of a building being erected on a section. permafrost soils.

The building includes a strip foundation 1, walls 2 made of wooden elements, PNS 3 beams, a flat roof 4, awnings 5, vertical external partitions 6, a wind generator 7, solar panels 8, perforated pipes 9, 10, an underground collector 11, drainage tanks 12 and drainpipes pipes 13.

Under the building, a strip foundation 1 is being erected. In a climatic zone where there is freezing of soils made up of clays, loams and sandy loams, a trench 20-25 cm wide is developed along the perimeter of the foundation. A trench filled with clay solution 14, prepared on the basis of diesel fuel. The depth of the trench is determined by the formula

H = Q / P x t,

where Q is the weight of the building, t;

P - the perimeter of the building, m;

t is the force of frost heaving, tn / m ² .

In the process of freezing of heaving soils, the soil solution in contact with the side surface of the foundation remains in a plastic state for the entire period of operation of the building and acts as a lubricant that compensates for the forces of frost heaving. Using a soil compensator eliminates the appearance of foundation sediments and deformation of the building.

Walls 2 are built of wooden log elements 15 (half logs), the manufacturing technology of which is as follows. The diameter of the logs for the manufacture of walls is no less than 15 cm, the requirements of SNIP are 22 cm. On both sides of the bark-free log, two edgings 16 are made (cut) and the log is given along the entire length the same size in longitudinal section. Then the log is cut along the diametrical plane passing through the piping into two halves. Both elements are joined together along the length so that the diametrical planes are turned in opposite directions, and the top of one half log is located with a thicker part (knot) of the half log of the other. Failure to do this will lead to the appearance between the elements 15 along the entire length of the uneven supporting area of the edges 16 and, therefore, a decrease in the strength characteristics and quality of the walls 2.

Elements made of one log are connected together along the entire length by screws 17, which are able to adjust the size of the wall in cross section. As the wall of wooden elements is erected, the space between them is filled with environmentally friendly heat-insulating material 18, for example, mounting foam. Due to the high adhesion (adhesion) of the binder material 18 to the tree, the wall 2 acquires high strength characteristics. The use of smaller logs and the manufacture of walls of a similar design makes it possible to reduce heat loss by more than three times and the cost of walls by 30-40% with an increase in the complexity of 15% in comparison with an analog (prototype).

As floor beams, wooden beams of increased bearing capacity (PNS) are used: PNS beam 3 consists of at least two wooden elements 19 (timber) and a plate 20 located between the elements, which has a high deformation ability with improved mechanical characteristics. The plates are made of high carbon steel or carbon fiber. Elements 19 are connected to the plate with glue, screws or rivets. The beam assembly is installed in strict accordance with its longitudinal axis.

The use of plates with reversible information eliminates the deviation of the beam from the longitudinal axis and allows you to provide the estimated bearing capacity. Experimental studies found that the plate 20 perceives 90% of the bearing capacity in the PNS beam. The wooden elements in the beam act as shells that are necessary for connecting with the roof elements, building walls and the supporting frame under the wind generator. Despite the increase in complexity in the manufacture of PNS beams in comparison with the analogue, its application will allow, all other things being equal, to increase the span length by 1.5-1.6 times and to abandon wooden trusses.

On the ceiling, made with a heat-insulating coating, place the roof 4, wind-shelter partitions 6 and awnings 5. Solar panels are laid on the wooden elements of the crate 8. The joint joints between the panels are filled with waterproofing material (mounting foam), ensuring the roof is airtight. Solar panels, in addition to its direct purpose, serve as a roof. The slope of the panel (i) for runoff of atmospheric water is taken equal to 0.01. Placing panels on the entire surface of the horizontal roof allows you to increase the area and, accordingly, the power of the solar installation.

Snow removal from the solar coating is performed using compressed air supplied by a household compressor to perforated pipelines. Pipelines include one central pipe 9 with a two-row arrangement of side holes and adjacent pipes 10, where the holes are made in one row and directed towards the walls of the building. Pipes 9, 10 are arranged parallel to each other and to the walls of the building. Such an arrangement of pipes and holes in the pipes allows you to remove snow from the roof of any shape and area in a short time with minimal energy consumption. For free flow of atmospheric water from the roof of the MEZ, pipelines are placed on linings 2-3 cm thick. In the installation for removing snow from the roof of the building, in addition to the compressor, an induction device is provided, which is a cylinder with a liquefied neutral gas - nitrogen.

The energy capacity of the building from the use of wind energy depends on the speed, volume of incoming air into the roof of the building and the direction of the wind. If air flows are directed perpendicular to the walls of the building, the power of the wind generator with a building area of 100 m ² and a wind speed of 5 m / s can reach 10 kW. When the wind direction deviates by 45 °, the power of the wind generator (building) is reduced by 4-5 kW. In this regard, on each wall of the building, vertical partitions 6 are fixed, which are able to change the horizontal direction of the wind to vertical. As a result of the use of vertical partitions 6, the power of the MEZ increases by 30-40%.

At the corners of the building, half-buried drainage tanks 12 are installed in the thermal shell 21. The tanks are interconnected by transfer polymer pipes 22, which are laid near the surface of the soil. A water heating element 23 is installed in one of the containers, and a load pump 24 is placed in the opposite container. The pump is designed to supply water to the building for domestic purposes. Water for irrigation of plants in the infield comes from tanks 12 under the influence of hydrostatic pressure. The constant flow of water from interconnected thermally insulated tanks, the use of a water heater and the underground location of the transfer pipes eliminates the freezing of water in the installation at low negative air temperatures.

The flow of water into the tank 12 is carried out through the drainpipes 13. In the spring season, when the air temperatures are alternating in the pipes 13, ice and ice plugs form. During this period, containers 25 with a perforated surface are fixed in the upper part of the drainpipes. The container cavity is pre-filled with calcium carbide 26 and technical salt 27. Melt water from the roof of the building enters the container, reacts with CaC ₂ , heats up to a temperature of 40-50 ° C and, thus, protects the surface from the formation of ice and ice plugs.

A collector 11 is laid in a trench next to the building in a trench shell 28 made of clay maximum moist soil. One end of the collector is connected to the air intake 29, the other is connected through the exhaust pipe 30 to the reduced pressure zone, which serves as the air space under the wind generator 7. Clay soil has the property of retaining moisture and not giving it away if there is no heat source nearby with high temperature. Therefore, the shell 28 acts as a natural cold accumulator in the device.

The cooling device operates in a flow-exhaust ventilation mode, in which the wind generator, temperature and air pressure gradients are the stimulating devices. A constant difference in air pressure in the device leads to air circulation in the manifold 11 and the exhaust pipe 30. The supply and volume of cold air in the building's premises is regulated by shutoff valves. In the winter season, the shell 28 of clay soil freezes. The accumulating capacity of the soil increases as another component of the atmospheric cold appears - the phase heat of melting of the ice. During operation, the device does not require electrical energy. Thus, the total energy capacity of the building, taking into account the use of all types of natural sources of energy, wind, sun, soil and phase heat of melting ice, can be in the range of 15-20 kW.

In the conditions of the spread of permafrost soils, the construction of low-rise buildings is carried out on pile foundations using an indoor cold underground. Permafrost soils are weak and, as a rule, heaving soils. Therefore, constant thawing and freezing of seasonal soil leads to the appearance of uneven precipitation of the foundation and deformation of buildings with small loads. When installing pile foundations, the drilling and launching method of piling 31 is currently used. As a result, the freezing time of piles, and therefore the construction of the building, is 6-7 months.

To solve this problem, a submersible submersible pile driving method is proposed, the essence of which is as follows.

A leader well is drilled at the site under the building, the diameter of which is taken 1.5-2 cm less than the diameter of the tubular steel pile. A tubular pile with a closed sharp end is installed in the drilled well. Piling is performed using an electric vibrator. Under the action of a vibrator, near-pile frozen soil 0.7-1.0 cm thick instantly turns into thawed soil. Pile immersion to a depth of 3 m occurs in 8-10 minutes. After this, the piles are left for freezing. In winter, the pile after diving is frozen with frozen soil for 2-3 hours.

The exclusion of the influence of frost heaving forces on piles in the soil layer of seasonal thawing - freezing is possible if this soil is left frozen for the entire period of operation of the building. To do this, in the warm season, periodically neutral gas - nitrogen - with a low negative temperature is supplied from a gas cylinder to the closed underground of the building. Preservation of the seasonal soil layer 32 under the building in a frozen state can significantly increase the bearing capacity of the foundation, reduce the depth of piling and increase the reliability and life of a low-rise building.

Despite the improvement of technical characteristics and economic indicators, a low-rise building with a flat roof is devoid of a variety of architectural forms. Given this circumstance, the building can be used in the construction of cottage villages mainly for owners with limited financial capabilities. In addition, a complete set of technical solutions cannot be used for any climate zone. So, for example, if the building is supposed to be located in a warm, dry climate, it makes no sense to use wooden walls and beams, a device to remove snow from the roof of the building, a device to prevent frost in the drainpipes and to install atmospheric water supply. Conversely, in cold climates there is no need for a soil-cooling device and a solar installation.

Claims (2)

1. Low-rise energy-generating building, including a foundation, walls made of wooden elements, wooden beams, a wind-covered roof, solar panels, a wind generator, an air-cooling device, a device for atmospheric water supply and drainpipes, characterized in that the building is equipped with a compensator of frost forces placed in the ground along the perimeter of the building, vertical partitions located perpendicular to the outer surface of the walls, and wooden beams of increased bearing capacity (PNS), while the pensioner is made in the form of a non-freezing layer of clay mortar and placed in contact with the side surface of the building, solar panels are placed on the entire surface of the roof of the building, each wooden wall element is made in the form of half-logs fastened together by adjusting screws, facing convex surfaces to each other, and heat-insulated expanded the material is placed between the half-logs to the full height of the walls, the PNS beam is made of at least two joined flat rectangular elements and is equipped with between the elements of a vertical plate with reversible deformation, the installation for removing snow is made in the form of one central pipe having two rows of side holes directed in opposite directions, and pipes adjacent to one row of holes facing the walls of the building, the air-cooling device is made in the form underground collector placed in a shell of clay maximum moistened soil and connected at one end to an air intake, the other to a zone of reduced air pressure in the roof of the building, GUSTs atmospheric water is in the form of interconnected insulated poluzaglublennyh the soil containers are placed under the downpipes, is provided with a submerged pump and water heating element, each drainpipe is provided with a perforated container filled with granules of calcium carbide and technical salt and having the ability to move through the pipe. 2. The low-rise energy-generating building according to claim 1, characterized in that during the construction and operation of the building in permafrost soils, a gas screen with a low negative temperature is periodically created in the underground of the building, and when immersing the tubular piles, a leader well with a diameter of two centimeters less than the diameter of the pile is used .

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