RU113818U1 - MODULAR EXHAUST VENTILATION SYSTEM FOR HEIGHT AND INDUSTRIAL BUILDINGS - Google Patents

Abstract

1. Modular exhaust ventilation system of high-rise and industrial buildings, consisting of ejection static-dynamic deflectors, ejection nozzles in the shafts of the deflectors and a system for supplying primary air to the ejection nozzles, characterized in that the ejection nozzles are made in the form of hydrodynamic accelerators with a Laval nozzle and are connected control valves to the riser pipe of the compressed air network supplied by the compressor. ! 2. Modular exhaust ventilation system according to claim 1, characterized in that each ejection static-dynamic deflector contains a conical diffuser, a cylindrical shell, an umbrella-cap and a throttle valve, while a vortex funnel with a hydrodynamic compressed air supply accelerator located tangentially to the vortex funnel body at an angle of 20 ÷ 22 ° upwards.

Description

The utility model relates to the field of engineering equipment of buildings and is designed to provide sustainable exhaust ventilation regardless of temperature and climatic conditions throughout the year. It can be used in residential, public and industrial facilities for emergency and smoke exhaust ventilation.

Static deflectors of various designs are used as devices for enhancing traction when air is ejected from individual and collective natural ventilation channels of residential and public buildings, from exhaust gas ducts and garbage chimneys (Schekin R.V. Handbook of heat supply and ventilation. Book 2. Ventilation .-- Kiev: Budivelnik, 1979. - p. 106 ÷ 117). The deflector is based on the use of wind energy. As a result of the wind flow around the deflector shell, a vacuum is created inside it (according to the Bernoulli law), under the influence of which air from ventilated rooms is removed to the atmosphere. Static deflectors have several disadvantages:

1. They work effectively only at a high wind speed - more than 2 m / s. At a lower speed, the device does not create a pressure difference (draft), but rather is an additional resistance for a natural exhaust ventilation system. With no wind during the warm season, the pressure loss on the vents exceeds the available pressure generated in the exhaust systems due to the temperature difference between the external and internal air, which leads to a violation of the ventilation of the premises of residential and public buildings.

2. Due to low productivity (even at significant wind speeds) they cannot be used as emergency ventilation and smoke exhaust devices in residential and industrial buildings.

In contrast to static devices for enhancing traction, stato-dynamic deflectors are equipped with additional mechanical elements and drivers of air movement. They allow you to keep the principle of natural ventilation virtually unchanged, as well as use all the advantages of mechanical ventilation at low capital and minimum operating costs.

Known stato-dynamic deflector with wind and mechanical motivation for exhaust ventilation systems of residential, civil and industrial buildings (Malakhov M. A. The project of natural-mechanical ventilation of a residential building in Moscow // ABOK. - 2003. - No. 3.). Structurally, this device is a combination of a static deflector with an axial exhaust fan. When the motor is off, the deflector has the technical characteristics of a static deflector and creates a vacuum equal to the sum of gravitational and wind pressures. When the electric motor is on, it creates a vacuum equal to the sum of the gravitational pressure and the pressure of the fan. The fan motor is included in the work only if necessary - with calm, not more than 20% of the entire time in a year, and is able to provide the necessary vacuum in the aerodynamic shadow zone, in ventilation systems of multi-level buildings, as well as in emergency ventilation of industrial buildings.

The disadvantage of this device is that in cases of fire in the deflector, the electrical communications and the fan, which are in the area of direct contact with high-temperature gases and can work on smoke removal for no more than 10-20 minutes, fail. As a result, high-rise buildings with similar devices quickly remain without smoke protection.

A disadvantage of the known device is also that the presence of a fan in each deflector makes it more expensive to build and maintain a building general ventilation system.

The closest in technical essence and the achieved result is a modular ejection exhaust ventilation system, which includes several static-dynamic deflectors with ejectors in the primary air (Olivia Noel. Natural ventilation activated by induction // Proceedings 21-st AIVC Annual Conference. Innovations in Ventilation Technology. - 26 ÷ 29 September. - 2000). Deflectors of such a system do not have a fan built into the housing, which allows them to be used as devices for smoke removal and emergency ventilation.

To create traction during calm periods (calm), each exhaust system deflector is equipped with an ejection nozzle installed along the axis of the ventilation shaft at the attachment point of the deflector. Primary air is supplied through the nozzle from a high-pressure fan located separately from the deflector. The air stream emerging from the nozzle nozzle rushes upward along the vertical axis of the deflector at a speed of 30-50 m / s and carries away (ejects) upward air from the lower part of the ventilation duct (secondary air). As a result of the energy exchange between fast and slow streams of air, the air velocity in the channel below the nozzle increases, the air velocity in the stream decreases, the total air flow in the ventilation channel increases several times.

The ejection ventilation system with stato-dynamic deflectors is modular, i.e. with one fan, the system can serve several ventilation shafts for various purposes. It can provide normative air exchange of residential, public and industrial buildings throughout the year under any weather conditions, more reliable and simpler than a mechanical ventilation system.

The disadvantage of the prototype is the low efficiency of using the fan power (≈30%) due to the small value of the ejection coefficient (the ratio of the flow rate of ejected air to the flow rate of ejection air) in the deflectors, which for this type of low-pressure devices does not exceed k _e = 3 at zero thermal and wind pressure. Due to its low efficiency and low productivity, the device is not widely used in emergency ventilation and smoke exhaust systems in residential and industrial buildings.

The purpose of the proposed utility model is to increase the efficiency of the exhaust ventilation system with ejection stato-dynamic deflectors, which will expand the range of applications of such systems in residential and industrial construction, including the period of summer calm and emergency conditions.

The result is achieved in that in a modular exhaust ventilation system consisting of ejection stato-dynamic deflectors, ejection nozzles in the baffles of the deflectors and a system for supplying primary air to the ejection nozzles, the ejection nozzles are made in the form of hydrodynamic accelerators with a Laval nozzle and connected via control valves to the pipe of the riser-receiver network of compressed air provided by the compressor.

The result is also achieved by the fact that each ejection stato-dynamic deflector of such a ventilation system contains a conical diffuser, a cylindrical shell, an umbrella cap and a throttle valve, while a vortex funnel with a hydrodynamic accelerator is installed between the throttle valve and the conical diffuser through which it is conical The diffuser is supplied with compressed air from a separate compressor. The accelerator is mounted tangentially to the body of the vortex funnel at an angle of 20 ÷ 22 ° up.

When these deflectors of a modular exhaust ventilation system operate in ejection mode, compressed air leaves the nozzle of a hydrodynamic accelerator at a speed of more than 200 m / s, while a mass-dynamic upward swirling stream of compressed air is created in the funnel, the energy potential of which creates additional work to increase traction inside the deflector with an ejection coefficient k _e from 3 to 6. A significant increase in the ejection effect in this case is explained by the first law of thermodynamics and mass-dynamic features a vortex developing according to the tornado model.

The utility model is illustrated in the drawings (figures 1, 2 and 3).

Figure 1 shows an ejection stato-dynamic deflector of a modular exhaust ventilation system containing a conical diffuser 1, a cylindrical shell 2, an umbrella cap 3. A throttle valve 4 is installed at the bottom of the deflector 4. A vortex valve is installed between the throttle valve 4 and the conical diffuser 1 a funnel 5 with a hydrodynamic accelerator of compressed air 6, the outlet of which is made in the form of a Laval nozzle. The accelerator 6 is mounted tangentially to the body of the funnel 5 at an angle of 20 ÷ 22 ° up. Compressed air is supplied at a pressure of 0.2 ÷ 0.6 MPa and, passing through the channel of the nozzle of the accelerator 6, is adiabatically accelerated in it to speeds close to the speed of sound (200 ÷ 270 m / s). As a result, an upward vortex flow is formed in the deflector housing according to the “tornado” model, which ensures the intake of ventilation air.

Figures 2 and 3 show schemes for using the utility model for general exchange exhaust ventilation of high-rise residential buildings and at fire and explosion hazardous production facilities.

Figure 2 shows a diagram of the device modular exhaust ventilation system when upgrading a typical workshop of category A and B, the rooms of which are divided into smoke zones 7. Each smoke zone 7 is equipped with ejection stato-dynamic deflectors that can use the wind pressure and the mass-dynamic potential of the vortex flows in emergency and off-season conditions. These deflectors are connected to the compressed air network from the compressor 8 with the receiver 9 through the control valves 10.

In figure 3. a diagram of the device modular exhaust ventilation system during the modernization of general exchange natural exhaust ventilation of high-rise residential buildings with a separate smoke removal system 11 from the stairwell areas. Ejection stato-dynamic deflectors 12 are installed on the floor-mounted prefabricated exhaust shafts. Compressed air from the compressor 8 is supplied to the deflectors 12 through automatic control valves 10 mounted on the leads to the pipe of the riser-receiver 13.

Exhaust ventilation, arranged according to the scheme of figure 3, a larger period of the year works in natural stimulation mode (in the presence of wind pressure); in non-standard conditions (with calm) and fire-emergency situation, the whole system switches to mass-dynamic mode. Due to the significant capacity of the riser-receiver 13, such a system can work for a long time when the power supply is interrupted, which is important to ensure the evacuation of people from the danger zone or upper floors of buildings. In addition, the modular exhaust ventilation system can provide significantly longer smoke removal at temperatures above 600 ° C, since there are no electrical communications or fans in the body of the ejection stato-dynamic deflectors.

As can be seen from the drawings, the proposed modular exhaust ventilation system with ejection stato-dynamic deflectors and one compressor can simultaneously serve several ventilation shafts for various purposes. It is also easy to install on existing buildings, since all of its main elements are mounted on the head of the ventilation duct, on the roof or attic.

In the proposed schemes, the thermal and wind effects of ventilation systems are not suppressed. The ejection circuit does not change the hydraulic resistance of the channels of the natural ventilation system. The compressor motor is automatically switched on by the signal of the differential pressure sensor at the outlet of the ventilation duct (with calm). The engine is also switched off by the signal of the differential pressure sensor (with high wind and temperature pressure) or by using a time switch (for example, after 60 minutes of operation - with emergency ventilation). In any case, it is possible to manually control the vents of the exhaust system.

Duplicate air compressors are installed in separate fire compartments or parts of buildings. According to estimates, the installation electric power of each should be ≈ 7 kW per 1 m ³ / min of compressed air. The volume of the receiver should be at least 30 ÷ 40% of the compressor capacity. When choosing the structural characteristics of the riser-receiver 13, operating at a pressure of up to 0.6 MPa, special requirements are not imposed, since in this case they do not differ from the requirements for pipelines of other engineering systems - heating and water supply. In addition, in the upper section of the riser-receiver 13 is equipped with a safety valve installed at a pressure of 0.6 MPa.

Thus, the proposed modular exhaust system for ventilation of high-rise and industrial buildings using ejection stato-dynamic deflectors allows you to create simple and reliable general-exchange exhaust and emergency ventilation circuits that maximize the use of wind energy during the greater period of the year, as well as the mass-dynamic potential of the vortex flows of compressed air during calm and in emergency situations.

The proposed schemes for using ejection stato-dynamic deflectors are very simple and do not require the installation of additional cameras and new structures. The only chamber for compressor equipment can serve as a central control panel for all ventilation systems and can be located in a separate zone.

The simplicity of the general exchange exhaust and emergency ventilation circuits with ejection baffles used in the proposed modular system makes it possible to extend it not only to newly designed buildings, but also to objects to be reconstructed.

Claims (2)

1. Modular exhaust ventilation system of high-rise and industrial buildings, consisting of ejection stato-dynamic deflectors, ejection nozzles in the deflector barrels and a system for supplying primary air to the ejection nozzles, characterized in that the ejection nozzles are made in the form of hydrodynamic accelerators with a Laval nozzle and are connected control valves to the pipe of the riser-receiver of the compressed air network provided by the compressor. 2. The modular exhaust ventilation system according to claim 1, characterized in that each ejection stato-dynamic deflector contains a conical diffuser, a cylindrical shell, an umbrella cap and a throttle valve, while a vortex funnel with a hydrodynamic is installed between the throttle valve and the conical diffuser an accelerator of compressed air supply, located tangentially to the body of the vortex funnel at an angle of 20 ÷ 22 ° up.