RU62938U1 - BUILDING ANTI-FLOOD DESIGN OF A BUILDING - Google Patents

Abstract

The proposed utility model relates to the field of construction, namely to the main elements of the building, which ensure its safety when exposed to high-speed water flows, mudflow with a wide range of changes in their level. The proposed support is most appropriate to use in the construction of individual houses, objects, the main load-bearing structures of which are made mainly of lightweight materials - wood, foam concrete, sandwich panels, etc.

The objective of the proposed utility model is to ensure its operation when exposed to high-speed flow of water or mudflows.

The problem is solved in that in the flood support structure of the building, containing a lifting device comprising two parts, the first of which is connected to the supporting structure of the building, the second part is connected to the embedded element, poured into the block-filling element, while the possibility of vertical movement of the first parts relative to the second to a distance corresponding to a fluctuation in the level of possible flooding, a hydraulic drive engine is used as a lifting device, e.g. an example, a vertically mounted hydraulic cylinder, the body of which is the first part of the lifting device, and its rod with the piston is the second part of the lifting device, the hydraulic cylinder is included in the hydraulic drive control circuit, which includes a container with oil connected to the suction line of the pump, the pressure line of which is connected to a safety valve and a filter connected through a safety valve to a distributor that performs the function of regulating the oil flow.

The flood control structure of the building can be equipped with an automatic triggering system, including an approaching breakthrough wave sensor connected to a comparison element, the output of which is connected to a threshold relay, the normally open contacts of which are included in the oil pump control circuit.

The flood support can be equipped with a protective stiffness barrier, which is installed after the support is activated in front of its stem in the probable direction of the breakthrough flow (wave) and is streamlined, for example, in the form of a cone sector with a base at the bottom, installed with an inclination

forming a cone towards the stem, the base body is interfaced with the block-filling element by means of a swivel joint, also equipped with a stop fixed in the working position of the stiffness barrier and designed to absorb the force acting on the protective barrier.

Figure 1-5 schematically presents an interpretation of the implementation of the proposed technical solution.

Figure 1 shows the support in section along the axis; figure 2 is a view of the support in the state of its operation in the presence of flooding of the terrain by a breakthrough wave; figure 3, a is a schematic hydraulic diagram of the "manual" control of the support (the initial state of the building and support, the distributor is in the neutral position; figure 3, b is the same, but the distributor is turned on for response to rise, the state of the support is on; 3 , c - circuit diagram of manual control of the electric motor of the oil pump; in Fig. 4, a - circuit elements of the automatic operation of the support; in Fig. 4, b - circuit diagram of the automatic inclusion in the operation of the electric motor of the oil pump; Fig. 4, c - circuit the hydraulic circuit of the support during its automatic actuation; in Fig. 5 is a view of the support in the state of its operation and in the operating position of the stiffness barrier - support protection).

Using the proposed building support allows, in the event of a breakthrough or mudflow wave at the location of the protected building, to timely raise the building above the level of flow, keep it in a “raised" state throughout the entire period of the flow, lower it and set it on the ground after the end of the action flow. At the same time, the negative impact of the flood flood on the building itself, the material assets located in it, as well as people, is excluded, and, in particular, the destruction of the building, damage to things, the health and, often, people's lives, are eliminated.

The indicated advantages have a cost equivalent, and the use of the proposed flood support of the building allows to obtain a social and real economic effect.

Description

The proposed utility model relates to the field of construction, namely to the main elements of the building, which ensure its safety when exposed to flooding and floods with a wide range of changes in their level. The proposed support is most appropriate to use in the construction of individual houses, the main supporting structures of which are made mainly of lightweight materials - wood, foam concrete, sandwich panels, etc.

Known building designs for the use of foundations in the form of pontoons. Taking into account the high cost of such foundations, the use of such structures, taking into account economic feasibility, is possible in special conditions - on the water. Another disadvantage of such structures is their unattractiveness from the point of view of architecture in traditional settlements located on land.

Known technical solution according to the patent of the Russian Federation No. 2074303, Cl. Е04Н 9/02, 1994 [1], the earthquake-resistant construction of the building which ensures its safety during floods. It contains a support with a stand fixed on the foundation with a bowl in its upper part, and a glass facing the bottom of the bowl, filled with liquid between them with a distance between the walls of the bowl and the glass, corresponding to the maximum amplitude of oscillations during an earthquake, and the glass is connected by reinforcement to the bottom a building block plate, which is placed with a clearance relative to the ground with a size not less than the maximum value of the vertical amplitude of oscillation and possible flooding.

A disadvantage of the known support is that it has: a) a large volume inside the bowl, and b) a large size between the support of the lower plate of the building block and the ground, which is determined by the maximum amplitude of oscillation and the maximum level of flooding recorded in a given area - sometimes several meters. The large size distorts the appearance of the building and creates difficulties in the architectural study. This is especially significant for low-rise individual construction.

Not relieved from this drawback and reliance on the patent of the Russian Federation No. 2143031, class. Е02Д 27/34, Е04 9/02, 1999 [2], which ensures the earthquake resistance of the building and its safety during floods, but having a more complex structure.

The closest technical solution to the proposed utility model is the support of the flood control structure of the building, on the application for which a positive decision to grant a patent was received [3]. The utility model adopted for the prototype contains a lifting device comprising two parts, the first of which is connected to the supporting structure of the building, the second part is connected to its foundation mounted on the earth's surface, while there is the possibility of vertical movement of the first part relative to the second by a distance corresponding to fluctuation in the level of possible flooding. As a foundation installed on the earth's surface, it is possible to use a block-filling element with a embedded element in it.

The support adopted for the prototype has the disadvantage that it only works efficiently with a slowly increasing level of water flooding of the area. At the same time, the container with the chamber is gradually filled with water and this creates the possibility of the subsequent “actuation” of the lifting device - the cup, with its edges facing down the chamber, by filling it with air. In this case, the time of filling the tank with water t ₁ and (plus) the subsequent filling of the glass with air and, accordingly, the rise of the building -t ₂ , as a rule, is less than the time of raising the water level of flooding on the ground or the impact on the protected building -t ₃ , i.e. t ₃ ≫t ₁ + t ₂ .

In the case of a sharp increase in the water level of flooding, for example, under the action of a wave breaking through the dam, or when a stream of water (mudflow) moving at a high speed is exposed to the protected building, i.e. when t ₃ <t ₁ + t ₂ , the known lifting device does not have time to work and raise the protected building. At the same time, the flow of water earlier acts on the building with its energy and destroys (demolishes) it before the water fills the container with the chamber, and subsequently fills it with air and lifts the building.

Thus, the support adopted for the prototype is not effective in resisting the effects of a moving stream of water, including a breakthrough wave formed as a result of the destruction of a pressure dam or resulting from other influences, for example, a tsunami.

The objective of the proposed utility model is to create a flood control structure of the building that would operate and protect it when exposed to a stream moving at high speed.

This object is achieved in that in the flood support of the building structure comprising a lifting device comprising two parts, the first of which is connected to the supporting structure of the building, the second part is connected to the embedded element poured into the block-filling element, and it is possible to vertically move the first parts relative to the second at a distance corresponding

fluctuation in the level of possible flooding. As a lifting device, a hydraulic drive engine is used, for example, a vertically mounted hydraulic cylinder, the body of which is the first part of the lifting device, and its rod with a piston is the second part of the lifting device, the hydraulic cylinder of the hydraulic system is included in the hydraulic drive control circuit, including a container with oil connected with the suction line of the pump, the pressure line of which is connected to the safety valve and the filter connected through the safety valve to the distribution divisor of performing the function of regulating the flow of oil ...

The flood control structure of the building can be equipped with an automatic triggering system, for example, containing a sensor of an approaching breakthrough wave connected to a comparison element, the output of which is connected to a threshold relay, normally open contacts of which are included in the oil pump control circuit.

The flood control structure of the building can be equipped with a protective stiffness barrier installed in the working position after the support is activated in front of its stem in the probable direction of the breakthrough flow (wave) and is streamlined, for example, in the form of a sector of a cone with a base at the bottom, installed with an inclined end towards the rod, the base of the barrier base is coupled to the block-filling element by means of a swivel joint, the barrier is also equipped with a stop, which is fixed in the working position of the barrier bone and designed to absorb the force acting on the protective barrier.

Figure 1-5 schematically presents an interpretation of the implementation of the proposed technical solution.

Figure 1 shows the support in section along the axis; figure 2 is a view of the support in the state of its operation in the presence of flooding of the terrain by a breakthrough wave; figure 3, a is a schematic hydraulic diagram of the "manual" control of the support (the initial state of the building and support, the distributor in the neutral position); figure 3, b - also (the distributor is included in the actuation - rise; state of the support is included); figure 3, c is a circuit diagram of a manual control of an oil pump electric motor; figure 4, a - elements of the circuit automatic response of the support; figure 4, b - circuit diagram of the automatic inclusion in the operation of the electric motor of the oil pump; figure 4, in - schematic hydraulic diagram of the support during its automatic operation; figure 5 is a view of the support in the state of its operation and the working position of the stiffness barrier - protection of the support.

Figure 1-5 introduced the following notation: 1 - building; 2 - supporting structure of the building; 3 - the surface of the earth; 4 - block-filling element with a embedded element; 5 - embedded metal element with which the rod of the lifting device is rigidly connected; 6 - continuation of the rod of the lifting device; 7 - hydraulic cylinder (HZ) of the lifting device; 8 - cylinder piston; 9 - stock GC; 10 - piston volume of the HZ; 11 - the over-piston volume of the HZ; 12 - line piston volume GC; 13 - line of the over-piston volume of the HZ; 14 - high-speed flow of water (breakthrough waves); 15 - pump; 16 - tank; 17 - filter; 18 - safety valve; 19 - check valve; 20 - a distributor; 21 - a protective barrier; 22 - metal emphasis; 23 - limiter; 24 - hinge of the barrier; 25 - a hinge of an emphasis; buttons: "Stop", "Start", PM - magnetic starter; 1PM - normally open contact of the magnetic starter; ~ 380V - AC voltage; 2PM, 3PM, 4PM - power normally open contacts of the pump “power”; Fiberboard - breakthrough wave sensor; _------ - image of the communication line; ES - element of comparison; X _I , X _s - the current value of the fiberboard signal and its set value, respectively; PR - threshold relay.

Protected from the effects of high-speed flood water flow, building 1 (Fig. 1) is installed on the supporting structure of building 2, which is installed on the surface of soil 3. The building is installed in an area exposed to high-speed water flow, water-earth mixture (wave of breaking through the dam, mudflow, tsunami and etc.) with a certain level of flooding. The supporting surface of the building 2 is rigidly connected to the housing of the hydraulic cylinder 7, which is the first part of the lifting device. The piston 8 of the hydraulic cylinder and its rod 9 are rigidly connected by extending the rod 6 with a mortgage element 5, poured into the block-filler element 4. The piston 8 with the rod 9, its extension 6 with the filler element 5 is the second part of the lifting device. Lines 12 and 13 are connected to the hydraulic cylinder (FIG. 2), through which oil (working fluid) can either enter the sub-piston space 10 of the hydraulic cylinder and the piston 8 will rise up (and the building rigidly connected to its body - down), or the over-piston space 11 of the hydraulic cylinder and the piston 8 will fall down (and the building rigidly connected to its body - up). To create oil pressure in the cavities of the hydraulic cylinder, the latter is included in the hydraulic circuit, which is shown in Fig.3, (as well as in Fig.3, b and 4, c). The circuit and its hydraulic elements are known [4, p. 268-270]. The suction line of the pump 15 is connected to the tank in which the oil is located. The pressure line of the pump is connected to the safety valve 18 (which opens when the line is blocked, for example, or the filter is dirty) and the filter 17. The filter 17 is connected through a safety valve 19 to the distributor

20. The distributor has 3 positions: forward, reverse and neutral. Thus, the distributor performs the function of regulating the direction of the oil flow (but not regulating the speed of the hydraulic cylinder rod. (The speed is controlled by the pump and depends on the load). Depending on the position of the distributor, the oil can be injected either into the piston cavity of the hydraulic cylinder (Fig. 3, b), either in the under-piston cavity of the hydraulic cylinder (not shown) or in the neutral position (Fig. 3, a). With "manual" control (Fig. 3, c), when the "Start" button is pressed, its contacts are closed, the PM magnetic starter coil is fed voltage, it is triggered by connecting its magnetic system (core), while closing a normally open 1PM blocking contact (the contacts of the "Stop" button are closed) and power contacts of the motor 15 of the pump.

For the case of automatic actuation of the support (4, a) X _Rin signal from the wave motion sensor breakthrough (DWT) on link EC is supplied to the comparison element, it enters the setpoint signal X _backside flow rate. The unbalance signal (X _ass -X _I ) = ± Δ is supplied to the threshold relay PR, normally open contact of which 1PR is connected in parallel with the contacts of the "Stop" button of the pump motor control circuit (Fig. 4, b). The distributor, in the automatic actuation position, is in the "Down" position (Fig. 4, c).

Taking into account the fact that when a high-speed flow (breakout wave) occurs, an extreme situation arises, in terms of energy supply (reducing its reliability), the proposed support design provides either autonomous power supply (autonomous portable power station, battery, etc.), or the use of a sealed extension cord centralized power supply and a flexible extension cord (flexible pipelines rolled into a ring) of a heat supply system.

After the protected building is brought into a raised state (support is activated), the people in it can either stay in it or leave the latter, for example, using a folding ladder and head to a safe place.

In Fig. 5, after the operation of the support, the protection barrier 21 of the support is brought into operation. This is done by turning the barrier 21, thanks to the hinge 24. The working position is provided by the stop 22, which is also brought into operation by the hinge 25 until it contacts the barrier 21, and is fixed in this position by the stop 23. In the working position, the barrier located in front of the stop and the upper end of which is higher than the level of the acting flow,

surfaces of the inclusion stream and objects (trees, structural details, etc.) and this prevents the occurrence of congestion and related complications in this place (at the support). 5, the arrow indicates the likely direction of flow and the position of the protective barrier.

The number of lifting devices can be more than one, depending on the size and weight of the house. In this case, protective barriers can be installed in front of the rod of each lifting device.

Works support flood design of the building as follows. Building 1 is installed on a supporting structure 2, which in turn is installed on the ground. If there is a threat of impact on the protected building of a moving flow of a breakthrough wave, for example, when a dam is destroyed, information about this is transmitted in advance (timely) through communication systems to settlements located in the territory where a breakthrough wave may arise. After receiving information about the occurrence of a breakthrough wave, the flood support structures of the buildings are brought into operation before the wave arrives before them. To do this, proceed as follows.

With manual control of the support. The handle of the distributor 20 is set to neutral. Press the “Start” button (Fig. 3, c), closing the PM magnetic starter coil circuit, which when the coil is pulled in, self-locks the contacts of the “Start” button (it is also on after releasing the “Start” button) and at the same time the power contacts 2PM, 3PM, 4PM turn on by which the electric motor 15 of the pump is turned on. In this case, the oil from the tank 16 (Fig. 3, a) is pumped by the pump 15 through the filter 17, the check valve 19 enters the distributor 20. In the normal position of the distributor 20, the oil enters the tank through the safety valve 18, thus circulating. To raise the building, the distributor is set to the "Up" position. When this oil is pumped into the over-piston space along the line 13 (figure 2), and from the under-piston space is thus displaced into the tank. When moving the piston 8 downward, due to the rigid connection of the cylinder head housing with the supporting surface of the building, the latter (the building) rises upward by the value of the piston stroke to 3.5 m ^*) (Fig. 2).

^*) It should be noted that hydraulic cylinders of various parameters — diameters, developed forces, piston stroke sizes [5, p. 94] have been developed and are commercially available, and methods for calculating the listed and other elements of the hydraulic network are known [5, p. 272-282].

If it is necessary to increase the amount of lift, a telescopic hydraulic cylinder with a simultaneous exit of steps can be used [4, p. 385-388], or

it is possible to use a system with automatic interception and sequential clamping of the rod [4, p. 477-478].

After raising the building, it is fixed in the raised position, for example, using a persistent mechanical lock (not shown in the illustrations). After that, the oil pump can be turned off by pressing the "Stop" button. After lifting the building 1, to protect the rod 9 from objects located on the surface of the moving stream 14 (trees, elements of building products, etc.), by preventing the formation of congestion at the support and their possible destruction, a protective barrier 21. For this, it is raised, thanks to the hinge 24, and thanks to the hinge 25, they raise the stop 22 and mate it with the barrier 21, using the stop 23 for fixing. The stop 22 perceives the force acting on the barrier 21, both of the stream itself and of the forces acting on the surface of the stream and in the stream items - trees, objects of building products, etc. Due to the fact that the upper end of the barrier 21 is above the level of the moving stream, and it has an oval shape (conical shape of the barrier), objects in the moving stream deviate from the barrier, and as a result, from downstream - stock. The indicated constructive measure prevents the formation of congestion in the area of the rods (supports) and possible subsequent destruction of the rods (supports) and increases the stability of the building in extreme conditions caused by high-speed flow. In the case of several supports (such a construction is possible with a large building, etc.) ^**) the same number of support barriers are installed.

^**) technical solutions for ensuring the synchronous operation of several hydraulic cylinders of a lifting device are known [6, p. 131, p. 140-144, p. 121-122].

Thus, in the proposed utility model, the response speed of the support is achieved, at which the time for its implementation (rise) is less than the arrival time of a moving high-speed stream, for example, when the dam is destroyed, to the protected building. Due to this, with the “approach” of the breakthrough wave to the protected building, the latter is already in the raised position (the support has already worked). At the same time, a moving stream of water (mudflow) and others does not affect the building (as it is raised), but acts on the supports (hydraulic cylinder rods). This helps to prevent the destruction of buildings and thereby reduce material losses and, even, save human lives.

After the end of the impact of the water flow (mudflow), the building is installed on the foundation - in its original state. To do this, after unlocking the mechanical lock and turning on the pump with the "Start" button, the distributor is moved to the "Down" position. When this oil pump 15 from the tank 16 (Fig.3, a) through the filter 17, the check valve

19, through the distributor 20 it enters the sub-piston space 10, the piston 8 moves up, and the building 1 rigidly connected to the main body of the cylinder falls down and is installed in its initial state (the position is shown in Fig. 1).

The disadvantage of manually controlling the operation of the proposed useful support is that in order to ensure its operation (bringing it into operation), it is necessary to have a person who would perform all the above operations to perform the operation.

With automatic remote control of the support. The distributor handle is set to the "Down" position (Fig.4, c). The normally open contact 1ПР of the PR threshold relay is connected to the contacts of the "Start" button. The breakthrough wave sensor (DVP) is remotely removed from the protected building in the direction of the probable direction of the high-speed flow occurrence, incl. flow waves. Breakthrough wave sensor via communication line communicates with ES comparison element (4 a), which is supplied along with the current value of a breakthrough wave signal approaching X _Rin predetermined breaking wave approximation signal X _s. At the output of the comparison element acts ES unbalance signal determined by the difference (X _Rin -X _s). With a positive value of the unbalance signal, the threshold relay PR is activated and its normally open contact 1PR closes. Connected parallel to the button contacts (Fig. 4, b) "Start", contact 1ПР closes the coil circuit of the PM magnetic starter, the latter trips and pulls in the detachable part of the magnetic circuit. In this case, the power contacts 2PM, 3PM, 4PM are closed and voltage is applied to the engine 15 of the oil pump. Oil from the tank 16 is pumped through the filter 17, the non-return valve 19, the distributor 20 through line 13 into the over-piston volume 11 of the hydraulic cylinder. In this case, the piston 8 lowers down, and the building support rigidly connected to the hydraulic cylinder body lifts it up (Fig. 5), and the oil from the subpiston volume is displaced along the line 12 into the tank. After raising the building 1, the support barrier is manually set by analogy with the sequence described above for the case of manual control of the support.

After normalization of the situation (the termination of the high-speed flow 14), the protective barriers are removed, the contact 1PR opens. To lower the building, the "Start" button is pressed. The building is lowered to its original state by lowering it down. To do this, the distributor is set to the "Up" position. Oil pump 15 (figure 4, c) it is pumped into the piston volume 10 of the hydraulic cylinder, the piston 8 rises up (the building is rigidly fixed with the piston of the hydraulic cylinder drops down).

The use of the proposed flood support of the building at high flow rates of flooding (breakthrough waves) allows you to "raise" in a timely manner

building above the surface of a moving stream of water (mudflows, tsunamis, etc.) and thereby prevent its negative impact on the buildings located on its way, people in them, material values and thereby increase the safety of the building structure, and obtain economic and social effects.

In addition, the use of the proposed utility model will allow you to get an effect in other technological problems and objects, including not related to the impact of high-speed flows, namely:

1. To create a lifting shelter for people, products, incl. dwellings in areas where dangerous and predatory animals dangerous to humans live (hunting, tourist houses, seasonal and military dwellings, including temporary facilities, observation posts).

2. Lifting viewing platforms for technical inspection of cars, for inspection of units located in the lower part of cars, the location of which is possible along highways. In this case, the operation of the lifting device is possible from the power system of the diagnosed vehicle.

3. Lifting platforms for periodic use (observation posts, including military, firing positions, lighting installations, antenna installations, trigonometric points, etc.).

4. Lifting facilities operating in water areas, incl. block-filling elements which are located at their bottom, approaches and entrances to them (objects of observation and review, points of food and entertainment, as well as recreation).

5. Lifting objects of urban infrastructure, the height and number of storeys of which can vary from the demand for the area, for example, time of year, time of day, etc.

SOURCES INFORMATION TAKEN INTO ACCOUNT

1. RF patent for the invention No. 2074303, Cl. ЕНН 9/02, 1994

2. RF patent for the invention No. 2143031, Cl. Е02Д 27/34, Е04Н 9/02, 1999

3. Patent of the Russian Federation for utility model No. 53343, “Support of flood-resistant construction of a building”. Stated May 30, 2005, Cl. 7E02D 27/32. Authors: A.D. Eliseev, O.A. Eliseeva, etc.

4. Gavrilenko B.A., Minin V.A., Rozhdestvensky S.N. Hydraulic drive. Engineering, 1968 - 502 s.

5. Vasilchenko V.A. Hydraulic equipment of mobile machines: Handbook - M.: Mechanical Engineering, 1983 - 301 p.

6. Bogdanovich LB Hydraulic drives Head Publishing House Association. Kiev, Vishka school, 1980 - 232 p.

Claims (3)

1. Flood support structure of a building, comprising a lifting device comprising two parts, the first of which is connected to the supporting structure of the building, the second part is connected to the embedded element poured into the block-filling element, with the possibility of vertical movement of the first part relative to the second distance corresponding to a fluctuation in the level of possible flooding, characterized in that a hydraulic drive engine, for example, a vertical, is used as a lifting device but the installed hydraulic cylinder, the body of which is the first part of the lifting device, and its rod with the piston is the second part of the lifting device, the hydraulic cylinder is included in the hydraulic drive control circuit, which includes a container with oil connected to the suction line of the pump, the pressure line of which is connected to the safety valve and a filter connected through a safety valve to a distributor that performs the function of regulating the oil flow. 2. Flood support structure of a building according to claim 1, characterized in that it is additionally equipped with a system for automatically operating it, comprising an approaching breakthrough wave sensor connected to a comparison element, the output of which is connected to a threshold relay, normally open contacts, which are included in the control circuit oil pump. 3. The flood control structure of the building according to claims 1 and 2, characterized in that it is equipped with a protective stiffness barrier, which is set in working condition after the support is activated in front of its stock in the probable direction of breakthrough flow (wave) and is streamlined in the form of a sector cone with the base below, installed with the inclination of the generatrix of the cone to the side of the rod, the base body is mated to the foundation by means of a swivel, is also equipped with a stop, fixed in the working position of the stiffness barrier and assigned to the perception of the force acting on it.