RU184488U1 - VENTILATION INSTALLATION FOR INSTALLATION ON THE BUILDING FACADE - Google Patents

Abstract

This utility model relates to electrical equipment, and more particularly to ventilation installations for mounting on a building facade, including a housing made in the form of a parallelepiped, inside which a fan is located. According to a utility model, the size of the sides of the parallelepiped is made from a ratio in which the size of the side of the parallelepiped located perpendicular to the facade of the building is greater than the width of the parallelepiped parallel to the facade of the building. Achievable technical result - the ability to reduce the surface area of the facade of the protective basket when the protective basket is in the form of a parallelepiped and when placing the ventilation unit together with other elements of ventilation and air conditioning systems in the specified protective basket on the building facade ..

Description

The technical field to which the utility model belongs.

This utility model relates to electrical equipment, and more particularly to ventilation installations for mounting on a building facade, including a housing made in the form of a parallelepiped, inside which a fan is located.

The following terms are used in this description:

A protective basket is a protective and decorative structure that is installed on the facade of buildings, covering the blocks of ventilation and air conditioning systems. Mostly performed in the form of a parallelepiped.

The facade of the protective basket is the surface of the parallelepiped of the protective basket, located with its visible part parallel to the facade of the building.

The width of the parallelepiped of the casing of the ventilation unit is the length of the side of the parallelepiped of the casing of the ventilation unit, which when it is installed is perpendicular to gravity and parallel to the facade of the building.

The level of technology.

Modern ventilation systems are designed to ensure complete air exchange, the correct distribution of air masses throughout the room and the formation of optimal microclimatic conditions for a comfortable stay of people.

The organization of high-quality ventilation is a difficult engineering task, for the solution of which individual calculations and the selection of the most suitable equipment are performed. There are a lot of types of ventilation units, and depending on the type of room, as well as the goals and objectives, certain equipment is selected.

By functional features, all ventilation units can be divided into three types:

• supply;

• exhaust;

• supply and exhaust

Fresh-air ventilation units serve for a constant influx of fresh air in the room, while it is pre-filtered, heated, cooled and, in some models, drained / humidified. Almost all models have the ability to regulate the set supply air temperature by heating or cooling (in the presence of a cooling unit).

The main purpose of exhaust ventilation systems is to exhaust the exhaust air from the room and evenly equalize the pressure with the current inflow. Exhaust ventilation units eliminate and remove not only unpleasant odors, but also remove various harmful substances from the room, such as carbon dioxide, dust, smoke, as well as other pollution and impurities dangerous to human health.

Air handling units are the most convenient, efficient and practical. They are widely used not only for private property, hotels, office buildings, but are also successfully used at large industrial enterprises, storage areas and workshops.

The proposed technical solution relates to ventilation installations for installation on the facade of a building of any type. Such installations are mounted on the facade of buildings in conjunction with other elements of ventilation and air conditioning systems and are protected on the outside with a protective basket.

Existing ventilation units are located along the facade of the building. That is, the size of the sides of the parallelepiped of such ventilation units is made from a ratio in which the size of the side of the parallelepiped located perpendicular to the facade of the building is smaller than either side of the parallelepiped parallel to the facade of the building.

But in this case, when installing such ventilation units together with other elements of ventilation and air conditioning systems, it is necessary to increase the size of the protective basket, which leads to an increase in the surface area of the facade of the protective basket. This is undesirable, as it leads to the consumption of material and occupies a visual majority of the facade of the building. In addition, problems may arise over a large area of icing in winter.

So known from the prior art ventilation installation for installation on the facade of the building, including a housing made in the form of a parallelepiped, inside which is a fan, see the description of patent for invention No. 2299358, published in 2013.

This device is the closest in technical essence to the claimed utility model and is taken as a prototype for the proposed utility model. The disadvantage of this device, as mentioned above, is the large surface area of the facade of the protective basket when the protective basket is in the form of a parallelepiped and when the ventilation unit is placed together with other elements of ventilation and air conditioning systems in the specified protective basket on the facade of the building.

That is, the problem that the present utility model is aimed at is the large surface area on the building’s facade, the inability to compactly place ventilation and air conditioning systems in a protective basket on the building’s facade.

Disclosure of a utility model.

The present utility model, based on this original observation, mainly aims to propose a ventilation installation for installation on the building’s facade, which includes a box made in the form of a parallelepiped, inside of which there is a fan that allows at least to smooth at least one of these above the disadvantages, namely, to provide the possibility of reducing the surface area of the facade of the protective basket when the protective basket is in the form of a parallelepiped and when placing the ventilation unit ste with other elements of the ventilation and air-conditioning systems in said protective basket on the facade of the building, which is the technical problem posed.

To achieve this goal, the size of the sides of the parallelepiped is made from a ratio in which the size of the side of the parallelepiped located perpendicular to the facade of the building is greater than the width of the parallelepiped parallel to the facade of the building

Due to this advantageous characteristic, it becomes possible to install the ventilation unit mainly perpendicular to the facade of the building, which allows to reduce the surface area of the facade of the protective basket when the protective basket is in the form of a parallelepiped and when placing the ventilation unit together with other elements of ventilation and air conditioning systems in the specified protective basket on the facade of the building .

There is a variant of the utility model in which the size of the side of the parallelepiped located perpendicular to the facade of the building is in the range 1.1-3.0 of the width of the parallelepiped parallel to the facade of the building.

Thanks to this advantageous characteristic, it becomes possible to select the most optimal aspect ratio of the parallelepiped of the ventilation unit body. Indeed, when choosing the size of the side of the parallelepiped located perpendicular to the facade of the building, less than 1.1 of the width of the parallelepiped located parallel to the facade of the building, there is a technical result, but it is not optimally expressed. And when choosing the size of the side of the parallelepiped located perpendicular to the facade of the building, more than 3.0 of the width of the parallelepiped located parallel to the facade of the building, there is a technical result, but a decrease in the efficiency of the ventilation unit begins to manifest itself undesirably. This is due to the fact that such a geometry of the case leads to a decrease in the size of the fan.

The set of essential features of the proposed utility model is unknown from the prior art for devices of a similar purpose, which allows us to conclude that the criterion of "novelty" for the utility model is met.

A brief description of the drawings.

Other distinguishing features and advantages of the utility model clearly follow from the description below for illustration and not being restrictive, with reference to the accompanying drawings, in which:

- figure 1 depicts the appearance of the placement of the ventilation unit together with other elements of ventilation and air conditioning systems on the facade of the building, according to the prior art,

- figure 2 schematically depicts a top view of the placement of the ventilation unit together with other elements of ventilation and air conditioning systems in a protective basket on the facade of the building, according to the prior art,

- figure 3 schematically depicts a top view of the placement of the ventilation unit together with other elements of ventilation and air conditioning systems in a protective basket on the facade of the building, according to the utility model,

- figure 4 schematically depicts a General view of the placement of the ventilation unit together with other elements of ventilation and air conditioning systems in a protective basket on the facade of the building, according to the utility model.

According to figures 2-4, the ventilation unit 1 for mounting on the facade 2 of the building includes a casing 11 made in the form of a parallelepiped, inside of which there is a fan 12. The size of the sides of the parallelepiped is made from a ratio in which the size of the side of the parallelepiped located perpendicular to the facade of the building is larger the width of the parallelepiped parallel to the facade of the building.

Mostly the size of the side of the box, perpendicular to the facade of the building, is in the range 1.1-3.0 of the width of the box, parallel to the facade of the building.

The figures also show:

3 - outdoor air conditioning unit,

4 - a protective basket.

Figure 1 shows how it is usually possible to arrange elements 1 and 3 in a protective basket 4. And in figure 2 - as proposed according to the utility model.

The arrow in FIG. 3 shows the direction of intake of street air into the ventilation unit. In the general case, the fence can also be carried out from other sides.

Implementation of a utility model.

The ventilation unit operates as follows. (An example of installation and operation not limiting the use of the utility model is provided).

Step 1. For mounting such an installation according to a utility model, the casing of the ventilation installation is made such that the side size of the parallelepiped is made from a ratio in which the side size of the parallelepiped located perpendicular to the facade of the building is larger than the width of the parallelepiped parallel to the facade of the building.

Stage 2. Install the ventilation unit on the facade of the building, together with other elements of ventilation and air conditioning systems, a protective basket on the facade of the building.

Step 3. Install a protective basket, which has a significantly smaller surface area of the facade of the protective basket.

The above embodiments of the utility model are exemplary and allow you to add new options or modify the described.

Industrial applicability.

The ventilation installation can be carried out by a specialist in practice and, when implemented, ensures the implementation of the declared purpose. The possibility of being implemented by a specialist in practice follows from the fact that for each feature included in the utility model formula based on the description, the material equivalent is known, which allows us to conclude that the criterion of “industrial applicability” for the utility model is consistent with the criterion of “completeness of disclosure” for utility model.

In accordance with the proposed utility model, the applicants manufactured a ventilation installation, which had a sign that the size of the sides of the parallelepiped was made from a ratio in which the size of the side of the parallelepiped located perpendicular to the facade of the building was greater than the width of the parallelepiped parallel to the facade of the building.

The pilot operation of such a ventilation installation that its design allows to achieve the achieved technical result is the possibility of reducing the surface area of the facade of the protective basket when the protective basket is in the form of a parallelepiped and when placing the ventilation installation together with other elements of ventilation and air conditioning systems in the specified protective basket on the facade building.

Claims (2)

1. The ventilation installation for mounting on the facade of the building, including a housing made in the form of a parallelepiped, inside which there is a fan, characterized in that the ventilation installation is made so that in the installed position of the ventilation installation the size of the side of the parallelepiped located perpendicular to the facade of the building is larger the width of the parallelepiped, parallel to the facade of the building. 2. The ventilation installation according to claim 1, characterized in that the size of the side of the parallelepiped located perpendicular to the facade of the building is in the range 1.1-3.0 of the width of the parallelepiped parallel to the facade of the building.

Images