RU2741951C1 - Supply ventilation unit - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: solution relates to the device of supply ventilation unit, intended mainly for placement inside ventilated room with wall mounting inside the room. Supply ventilation unit includes a housing designed for indoor installation; air inlet; at least two output channels; and at least two purification units, each of which is configured to purify air passing through a corresponding outlet channel. Installation includes a centrifugal fan, at least partially located in the casing, and containing a central part in which the fan impeller is located; at least two outlets, each of which is pneumatically connected to the central part of the fan and to a corresponding outlet channel; and a common inlet pneumatically connected to the fan center and the air inlet.

EFFECT: said invention provides increased productivity of supply ventilation unit while maintaining a low noise level, efficiency of cleaning supplied air, energy consumption and smaller area occupied by unit in the room.

5 cl, 2 dwg

Description

TECHNICAL FIELD OF THE INVENTION

The technical solution relates to the field of room ventilation. More specifically, the technical solution relates to the device of the supply ventilation unit, intended mainly for placement inside a ventilated room with wall mounting inside the room.

LEVEL OF TECHNOLOGY

From the publication of the patent RU 2708105 dated 04.12.2019, a ventilation installation is known, comprising a housing made with the possibility of installation along the wall inside the room, an inlet channel for air running through the side of the housing, in the installed position located along the wall of the room, and preferably adjacent to the wall of the room , and the output channel. In this case, the known installation contains a filter capable of cleaning air passing through the inlet channel. In this case, the installation includes a centrifugal fan of the "snail" type, the inlet of the casing of which is pneumatically connected to the inlet for air.

The disadvantage of the known solution is that with an increase in the performance (flow rate or rotation speed of the impeller) of the fan, the noise level increases significantly and the efficiency of cleaning the air supplied to the room decreases. To increase the performance of a ventilation unit of a known design, it is necessary either to increase the rotation speed of the fan impeller (this increases the noise level and reduces the efficiency of air purification); or to increase the size of the fan and the cross-sectional area of the ducts, which will lead to an increase in the dimensions of the entire ventilation unit and, accordingly, the area of the room occupied by the unit in the room, and this is extremely undesirable if it is used in residential premises.

It is necessary to understand that the noise generated in the duct is the higher, the higher the speed of air movement in the duct. At the same time, to ensure the required indoor air quality, it is required to create a fresh air flow, the performance of which is mainly determined by the volume of the room. Such a performance at a certain size of the cross-sectional area of the air duct outlet corresponds to a certain air velocity and a certain level of noise generated in the duct due to the movement of air in it.

The most suitable method for determining the noise level generated by a duct is presented in the reference [2] (Engineering ToolBox, (2008). Noise Generated in Air Ducts. [Online] Available at: https://www.engineeringtoolbox.com/ducts-noise- generation-d_1405.html [available 03.26.2020]), it also corresponds to the methodology in the source [3] (clause 6.4.3 "Sound attenuation systems for air heating, ventilation and air conditioning", set of rules JV 271.1325800.2016, approved by order of the Ministry of Construction and housing and communal services of the Russian Federation dated December 16, 2016 No. 959 / pr) and is calculated as follows:

Lw = 10 + 50 log (v) + 10 log (A), where

Lw = sound power level, dB; v = air speed, m / s; A = cross-sectional area of the duct in m2.

That is, in a round duct with a diameter of 0.2 meters at an air speed of 20 m / s, noise will be generated at the level of 60 dB, and at a speed of 10 m / s in the same duct - 45 dB. The speed of air movement in the duct is proportional to the volume of air passing through it per unit of time. That is, this speed is dictated by the required performance of the ventilation system.

In order to reduce the noise level created in the duct by a flow of such a capacity, it is possible to resort to increasing the cross-sectional area of the duct, into which air is pumped by a centrifugal fan. This path increases the dimensions of the duct, which is a critical parameter when placing the duct indoors.

At the same time, an increase in the speed of air movement through the cleaning unit negatively affects the efficiency of air filtration. This is confirmed by the dependence presented in the source [Birger MI, Valdberg A.Yu., Myagkov BI. Handbook of dust and ash collection. Publ. in 1983; P. 150. Formula (5.1).]:

The efficiency of diffusion deposition of particles in the case of using fibrous (or porous, sieve) filters can be represented as a dependence:

where d _in - the diameter of a fiber, grain or other element forming a porous partition, m; ω - gas velocity, m / s; d _h - particle diameter; A is the proportionality factor.

Thus, an increase in the air velocity through the filter reduces the filtration efficiency in the case of porous filters.

The case of using electrostatic dust collectors and filtering materials is analyzed in the source: [VN Bogoslovsky, VI Novozhilov, BD Simakov, VP Titov. Ventilation. Part II., Publ. in 1976, pp. 227-229, 234-237]. In these cases, also with an increase in the speed of air movement through the purification unit, the filtration efficiency decreases.

In addition, ultraviolet emitters are often used in air purification units. Obviously, their effectiveness also depends on the time of exposure of the radiation to the particles passing through the irradiated area, and, consequently, on the speed of these particles movement through the irradiated area. Accordingly, the speed of air movement also negatively affects the efficiency of the disinfection irradiators.

The negative effect of air velocity on energy consumption is described in the source [Shtokman E.A. Ventilation, air conditioning and air purification in the food industry. Publ. in 2001; P. 196-197. Formula (6.15).].

The hydraulic resistance is important, since the required fan pressure and, consequently, the power consumption depends on its value. The hydraulic resistance of the apparatus is determined by the formula:

where v is the speed of air movement through the apparatus, m / s; A, n - coefficients determined experimentally and depending on the design of the apparatus.

The consumption of electrical energy largely depends on the hydraulic resistance of the apparatus, which in turn nonlinearly depends on the speed of air movement through the apparatus and the design of the apparatus itself.

That is, an increase in the performance of an air purifier by increasing the speed of air movement leads to an increase in the noise level, a decrease in the quality of purification and an increase in energy consumption.

On the other hand, an increase in the cross-sectional area of the air ducts significantly increases the required dimensions of the installation. And when placing the fan inside the room, its dimensions are of great importance: the more compact the device is, the better.

DISCLOSURE OF THE INVENTION

The task facing the developers of the disclosed technical solution was to create a design for a supply ventilation unit that would increase the unit's performance while maintaining a low noise level, efficiency of cleaning the supplied air, energy consumption and a small area occupied by the unit in the room.

The task was solved by creating a supply ventilation unit, which includes

an enclosure designed for indoor installation;

air inlet;

at least two output channels; and

at least two purification units configured to purify air passing through the corresponding outlet channel;

the installation includes

centrifugal fan, at least partially housed in the housing, and containing

the central part, which houses the fan impeller;

at least two outlets, each of which is pneumatically connected to the central part of the fan and to a corresponding outlet channel; and

common inlet, pneumatically connected to the central part of the fan and the air inlet.

The technical result achieved by the disclosed technical solution consists in providing the possibility of increasing the performance of the supply ventilation unit while maintaining a low noise level, efficiency of cleaning the supplied air, energy consumption and a small area occupied by the unit in the room.

In fact, the disclosed design of the installation allows increasing the productivity of the installation by changing its overall dimensions, which run along the axes, which are essentially parallel to the wall of the room, to which the supply ventilation unit is adjacent in the installed position, while not changing its dimensions along the axis, which is essentially perpendicular to the wall. Thus, the design allows increasing the performance of the air handling unit without changing the area occupied by the unit in the room.

Hereinafter, the disclosed technical solution will be described in more detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF DRAWINGS

Fig. 1 is a schematic view of the housing of the supply ventilation unit in one of the embodiments of the technical solution.

Fig. 2 is a schematic view of the housing of the supply ventilation unit with installed cleaning units in one of the embodiments of the technical solution.

MODES FOR CARRYING OUT THE INVENTION

In accordance with the disclosed technical solution, the supply ventilation unit 1 includes a housing 2 made with the possibility of installation (installation) inside the room. In a preferred embodiment, the housing of the ventilation unit is mounted (installed) along the wall inside the room on the wall. The unit is intended for installation mainly indoors on the wall separating the premises and the street. The possibility of indoor installation assumes that the ventilation unit, on the one hand, is made with the possibility of fixing it inside the room, on the other hand, it is made with the possibility of taking air from the external environment to pump it into the room. Embodiments of this possibility are disclosed below. The possibility of air intake from the external environment can be ensured due to the fact that the ventilation unit is made with the possibility of pneumatic connection to an air duct running through the wall of the room. In a preferred embodiment, such an air duct is made in the form of a tubular air duct located essentially perpendicular to the side of the installation, in the installed state located along the wall of the room; the air duct is pneumatically connected to the air inlet.

The possibility of mounting the housing on the wall of the room inside the room can be realized due to the presence of means for securing the installation on the wall of the room, including lugs or holes for anchors, and / or other means of fastening the installation (not shown). As one of such means of fastening, a device for fastening ventilation equipment, similar in principle to the solution disclosed in patent RU 154823 (publ. 09/10/2015), can be used. This publication assumes that the ventilation unit is installed outside the premises (for example, on the facade of a building). Obviously, it is possible to fix the ventilation unit in the same way by means of a ventilation hole (through the duct) passing through the wall of the building. Thus, the means for fixing the installation on the wall of the room may comprise a pin extending along the air duct passing through the building wall to the outside, as well as means for fixing the corresponding ends of the pin from the inner and outer sides. Installation in accordance with this technical solution may include other means of fixing the installation on the wall of the room, which does not limit the scope of this technical solution.

In accordance with the present technical solution, the supply ventilation unit includes an inlet channel 3 for air, as well as at least two outlet channels 4a and 4b. The present technical solution does not require the installation of any cleaning or heating units in the inlet channel, however, in some embodiments, the ventilation unit can be equipped with additional devices in the inlet channel 3.

In this case, the ventilation unit includes a centrifugal fan containing

the central part 6, which houses the fan impeller 7,

at least two outlets, each of which is pneumatically connected to the central part of the casing and to a corresponding outlet channel (4a and 4b); and

common inlet, pneumatically connected to the central part of the fan and the air inlet 3. The centrifugal fan in a preferred embodiment is at least partially housed in the housing 2. In some embodiments, portions of the fan (for example, the inlet and / or one or more outlets may protrude outside the housing 2. It should be understood that in some embodiments the implementation of the centrifugal fan comprises a casing 5 containing the impeller 7 of the fan and, in some embodiments, at least two outlets, and there are also possible embodiments in which the housing 2 of the ventilation unit 1 acts as a casing 5 of the centrifugal fan, and parts fans are located in the casing 2 of the unit 1. Under the central part 6 of the centrifugal fan, it is necessary to understand the limited volume inside the casing 2 of the ventilation unit 1, in which the impeller 7 of the centrifugal fan, by its rotation, creates an excess pressure; due to this, air is removed from the central part 6 goes through the corresponding outlet openings into the corresponding outlet channel 4a and 4b.

In this case, the inlet channel 3 for air runs through the side of the housing 2, in the installed position of the ventilation unit 1 located along the wall of the room. In one of the embodiments of the technical solution, the inlet channel 3 for air is an opening in the wall of the housing 2, made with the possibility of pneumatic connection of the external environment with the inner part of the housing 2, namely, with the central part of the casing 5 of the centrifugal fan, in which the impeller 7 is located centrifugal fan. For the purposes of this description, the external environment should be understood as the space from which air is forced into the room; in a preferred embodiment, the external environment refers to the street.

The impeller 7 of the centrifugal fan in preferred embodiments is made in the form of an impeller with blades located radially, or curved and / or inclined backward relative to the direction of rotation of the impeller 7 of the fan.

The air inlet 3 includes an opening in the casing, which is pneumatically connected to the inlet of the centrifugal fan casing. Also, the ventilation unit for air can include an air duct that protrudes beyond the dimensions of the housing 2, in the installed position of the ventilation unit 1 passes through the wall of the room, and is also configured to provide a pneumatic connection of the external environment with the air inlet channel 3 when the air duct is placed in through a hole in the wall of the room. In fact, in this case, the air duct can form a continuation of the inlet channel 3. It can be considered that the said air duct is part of the inlet channel 3. In a preferred embodiment of the technical solution, the said air duct is configured to be placed in a through hole in the wall of the room, that is, in the installed position passes through the wall of the room perpendicular to its surface and is pneumatically connected to the external environment. In a preferred embodiment, the duct is substantially coaxial with the air inlet 3, most preferably the duct and the air inlet 3 are also substantially coaxial with the impeller 7 of the centrifugal fan.

In a preferred embodiment of the disclosed technical solution, the ventilation unit 1 is mounted (installed) on the wall inside the room in such a way that its inlet channel 3 is in working condition aligned with the hole in the wall of the room. In accordance with the present technical solution, the ventilation unit 1 also includes at least two outlet ducts 4a and 4b. In this case, the centrifugal fan, when the impeller 7 rotates, sucks air through the inlet channel 3 and the inlet of the casing 5 of the centrifugal fan into the central part 6 of the casing 5 of the centrifugal fan and then - pumps air into the room through at least two outlets and corresponding at least two output channels 4a and 4b.

For the purposes of this description, the term "channel" should be understood as an artificially created path through which air can move. In this case, the channel can include both air ducts, openings and / or cavities, and functional blocks, which are made with the possibility of passing air through themselves, additionally in some way to process and / or transform this air; for example, cleaning, changing its temperature, its direction of movement, its speed of movement and / or pressure.

In accordance with the present technical solution, the ventilation unit includes at least two purification units 8a and 8b, configured to purify air passing through the corresponding outlet duct 4a and 4b. In the embodiment of the technical solution shown in the figures of the drawings, the cleaning units 8a and 8b are made as separate units installed outside the housing 2, however, in other embodiments, the cleaning units 8a and 8b can be at least partially enclosed inside the housing 2. In this case in the embodiment shown in the figures of the drawings, the purification unit 8a (conditionally - the first purification unit) is configured to purify air passing through the outlet channel 4a (conditionally - the first outlet channel), and the purification unit 8b (conditionally - the second purification unit) is made with the possibility of cleaning the air passing through the outlet channel 4b (conditionally - the second outlet channel).

The purification units 8a and 8b may include at least one of the following units: a dust filter, a photocatalytic filter, an adsorption filter, an electrostatic dust collector, a fibrous filter (e.g. sieve and / or porous), an ultraviolet irradiator, or any other units and devices made with the ability to filter, disinfect and / or otherwise purify air from various unwanted impurities.

In one embodiment of the present technical solution, the supply ventilation unit includes at least one air heating unit configured to heat the air passing through the corresponding outlet duct. In a preferred embodiment of the present technical solution shown in the figures of the drawings, the supply ventilation unit 1 includes at least two air heating units 9a and 9b configured to heat the air passing through the corresponding at least two outlet ducts 4a and 4b. That is, the air heating unit 9a (conditionally - the first air heating unit) can be configured to heat the air passing through the first (lower) outlet channel 4a, and the air heating unit 9b (conditionally - the second air heating unit) is configured to heat the air passing through the second (upper) outlet channel 4b.

The at least one air heating unit 9a and 9b may include any of the known heating elements, for example a ceramic heater.

In the embodiments of the disclosed technical solution, in which the supply air handling unit 1 comprises one air heating unit, it is preferably configured to heat the air passing through the outlet duct, forcing air into the lower part of the room. In the embodiments of the disclosed technical solution, in which the supply ventilation unit 1 contains at least two air heating units 9a and 9b, the unit 1 is preferably configured with the possibility of separate regulation of the temperature (or heating power) of the air in different outlet ducts. So, in order to create the most comfortable microclimate in the room, the air blown through the outlet ducts to the lower part of the room can be heated to 22-24 ° C, and the air blown through the outlet ducts to the upper part of the room can only be heated up to 15-19 ° C, or do not heat up at all, depending on the ambient air temperature and the target indoor microclimate. Such separate regulation allows to improve the air quality, the comfort of the indoor climate, while reducing the energy consumption of the ventilation unit 1.

In the disclosed technical solution, by increasing the number of outlet channels and increasing the total cross-sectional area of the outlet channels 4a and 4b, it was possible to increase the performance of the ventilation unit 1 while maintaining the air velocity inside the unit, noise generated due to air movement in the unit channels, cleaning efficiency of forced air without increasing the space occupied by the installation inside the room. At the same time, an increase in the total area of the outlet ducts reduces the hydraulic resistance of the unit (this also reduces the pressure in the casing of the centrifugal fan, which is required for pumping air into the unit), which reduces the energy consumption of the ventilation unit. At the same time, in the case when the installation operates at the same performance level as the installation in accordance with the prototype, the air velocity in the installation, in accordance with the disclosed technical solution, is lower than in the prototype, and the level of noise and energy consumption is also reduced, and also improved the efficiency of air purification.

Also, a decrease in the air speed makes it possible to reduce the power of the air heating units 9a and 9b. In some embodiments, in which separate regulation of the air heating temperature by the air heating units 9a and 9b is performed, it is possible to more efficiently distribute warm air in the room while improving the microclimate, which also further reduces energy consumption without compromising other characteristics of the installation.

In other embodiments of the implementation of the technical solution, the ventilation unit 1 may include a larger number of outlet channels 4a and 4b and cleaning units, which will further increase the performance of the ventilation unit without compromising the listed characteristics.

The present technical solution has been described in detail with reference to individual variants of its implementation, however, it is obvious that it can be implemented in various versions, without going beyond the claimed scope of legal protection defined by the claims.

Claims (5)

1. Supply ventilation unit, including a housing made with the possibility of indoor installation, an inlet channel for air, at least two outlet channels and at least two cleaning units, each of which is configured to clean air passing through a corresponding outlet duct, while the installation includes a centrifugal fan, at least partially located in the housing, and containing a central part in which the fan impeller is located, at least two outlets, each of which is pneumatically connected to the central part of the fan and to the corresponding outlet, and a common inlet, pneumatically connected to the central part of the fan and the air inlet. 2. The supply ventilation unit according to claim 1, characterized in that the unit includes at least one air heating unit configured to heat the air passing through the at least one corresponding outlet duct. 3. The supply ventilation unit according to claim 1, characterized in that the unit includes at least two air heating units configured to heat air passing through the corresponding at least two outlet channels, while the ventilation unit is configured to separate regulation of the temperature of heating the air in the outlet channels. 4. Supply ventilation unit according to claim 1, characterized in that the inlet air duct runs through the side of the housing, in the installed position located along the wall of the room. 5. The supply ventilation unit according to claim 4, characterized in that the ventilation unit includes an air duct protruding beyond the dimensions of the housing and configured to provide a pneumatic connection of the external environment with the air inlet channel when the air duct is placed in a through hole in the wall of the room.

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