RU174370U1 - VENTILATION DEVICE WITH RADIAL OUTLET AIR FLOW - Google Patents

Abstract

A ventilation device with a radial outgoing flow solves the problem of supplying the room with fresh air at an increased flow rate of the outgoing flow, increased efficiency and low noise levels. 2). The outgoing section of the duct (1) expands funnel-shaped and together with a conical septum (3) forms a radial outlet for air. The cone-shaped partition (3) is located behind the fan in the direction of the air outlet and looks like a truncated cone with a gradually increasing diameter. A fairing (4) is attached in front of the fan hub (2).

Description

Technical field

The utility model relates to a ventilation device with an axial fan and radial outflow for supplying the room with fresh air.

Prior art

A ventilation device with a radial outgoing flow is known, which consists of a pipe with an axial fan placed in it and a front partition in the area of the outgoing air deflecting the outgoing air flow in the radial direction.

The disadvantages of this fan are high noise levels, as well as large losses due to direct meeting of air with the front partition, which reduces the flow rate and efficiency of the device.

Utility Model Technical Essence

The objective of the utility model is to create a ventilation device with an axial fan and a radial outgoing flow with an increased flow rate of the outgoing air, improved efficiency and low noise levels.

The problem is solved using a ventilation device with an axial fan and a radial outgoing flow, in which the duct and the front partition have a special shape.

According to a utility model, a ventilation device with a radial outflow consists of an air duct and an axial fan (2) placed in it. Moreover, the duct, characterized in that it contains the first incoming cylindrical section with an inner diameter D1; a second cylindrical section with an inner diameter D2 in which the axial fan blade is located; the third outgoing funnel-shaped section. In this case, the cone-shaped partition is located directly behind the hub of the fan blade towards the outlet of the duct (1). The specified partition is a body of revolution with a continuous conoidal rounded surface, obtained on the basis of a curved, concave generatrix, fully or partially smooth. The conical septum faces its small base to the hub of the fan blade. Moreover, the small base of the conical septum has a diameter corresponding to the diameter of the hub. Moreover, between the outer surface of the conical septum and the inner surface of the third outgoing section of the duct, a radial air outlet is formed, since the diameter of the third outgoing section gradually increases outward to the outlet of the duct, so that the width of the radial air outlet increases smoothly from the hub area to the outlet air duct.

Preferably, the rounded surface of the conical septum is formed on the basis of a circular arc and is part of a circular toroid.

In a preferred embodiment of the utility model, the inner diameter D2 of the second cylindrical portion is larger than the inner diameter D1 of the first incoming cylindrical portion. Moreover, at the boundary between the first incoming cylindrical section and the second cylindrical section, a step of the inner surface of the duct is formed, since the difference between D1 and D2 corresponds to the gap between the blade and the inner surface of the second cylindrical section.

Preferably, between the fan blade with the maximum width and the inner surface of the second cylindrical section of the duct there is a technologically permissible minimum gap.

Preferably, directly in front of the hub of the blade, in the direction of air flow, a fairing is attached, which is a body of revolution with a conoidal surface based on a curved convex generatrix, and with a base having a diameter corresponding to the diameter of the hub.

The above-described design of the ventilation device, according to the utility model, provides a smooth exit of air, preventing its swirling, which leads to an increase in the flow rate of the outgoing air and, consequently, to an increase in the efficiency of the device, as well as to a decrease in the noise level.

Explanation of the attached figures

A more detailed utility model is shown in FIG. 1, a longitudinal section through a ventilation device.

An example of the invention

Shown in fig. 1, a ventilation device, according to a utility model, consists of a duct (1) of circular cross section with an axial fan (2) located therein. The axial fan (2) is mounted in the duct (1) in a standard way. For the duct (1) it is characteristic that it consists of three consecutive sections.

The first section is the incoming cylindrical section (1.1) with an inner diameter D1.

The next section is the second cylindrical section (1.2) with an inner diameter D2 and the fan blade located in it (2.1).

In a preferred embodiment of the device, the inner diameter D2 of the second cylindrical section (1.2) is larger than the inner diameter D1 of the first incoming cylindrical section (1.1), and a step of the inner surface is formed at the boundary between the first incoming cylindrical section (1.1) and the second cylindrical section (1.2) duct (1). The difference between the values of D1 and D2 is equal to the gap between the fan blade and the inner surface of the second cylindrical section (1.2). The purpose of this stage is to reduce the turbulence of the air flow near the inlet of the duct.

Preferably, the gap b between the fan blade (2.1) and the inner surface of the second cylindrical portion (1.2) corresponds to the technologically permissible minimum distance, which ensures smooth rotation of the blade during operation of the fan.

The third outgoing section (1.3) has a funnel shape, and its diameter gradually increases in the direction of the air outlet. In this case, the inner surface of the third section (1.3) is initially parallel to the axial line of the axial fan (2) and then passes into a plane perpendicular to this axial line. The small diameter of the third section (1.3) coincides with the diameter D2 of the second cylindrical section (1.2).

Behind the fan (2) and on the same axis with it, towards the outgoing air hole, there is a cone-shaped partition (3) in the form of a wrapped truncated cone with a concave surface. The diameter of the small base of the septum corresponds to the diameter of the hub (2.2). The diameter of the partition (3) gradually increases in the direction of air flow until the axial opening of the duct (1) is closed, providing a deviation of the outgoing air flow in the radial direction.

The conical septum (3) is a solid body of revolution with a fully or partially smooth continuous conoidal rounded surface based on a curved concave generatrix. In a preferred embodiment of the device, the rounded surface of the conical septum (3) is formed on the basis of an arc of a circle and is part of a circular toroid.

In this design, between the outer surface of the conical partition (3) and the inner surface of the third outgoing section (1.3) of the duct (1), a radial air outlet is formed, since an increase in the diameter of the third outgoing section (1.3) outward to the outlet of the duct is thus organized that the width of the radial air outlet increases smoothly from the area of the hub (2.2) of the fan (2) to the outlet of the duct (1).

The design of the radial outlet allows you to provide laminar (without turbulence), silent and with minimal losses, the output of the outgoing air.

In a preferred embodiment, immediately in front of the hub (2.2) of the blade (2.1), in the direction of air flow, a fairing (4) is placed on the same axis as the fan, which represents a body of revolution with a conoidal surface, based on a curved convex generatrix, and having a base with a diameter corresponding to the diameter of the hub (2.2) of the blade (2.1). The cowling (4) is facing with its base to the fan (2), while its top is directed towards the inlet of the duct (1). Fairing (4) is designed to direct the incoming air flow in the radial direction.

Claims (5)

1. A ventilation device with a radial outgoing stream, consisting of an air duct (1) and an axial fan (2) placed in it, characterized in that the air duct (1) consists of a first incoming cylindrical section (1.1) with an inner diameter D1, a second cylindrical section (1.2) with an inner diameter D2, while in the second cylindrical section (1.2) there is a blade (2.1) of the axial fan (2), and the third outgoing section (1.3) is funnel-shaped, the diameter of which gradually increases as it approaches the exit near the duct, in this case, in the direction to the outlet of the duct (1), immediately after the hub (2.2) of the blade (2.1), on the same axis as the fan (2), there is a conical partition (3), which is a body of revolution with a continuous conical rounded surface formed by a curvilinear rotation a concave generatrix around the axis, while the conical partition (3) faces its small base to the hub (2.2), while the small base of the conical partition has a diameter corresponding to the diameter of the hub (2.2) of the blade (2.1), when that, since the diameter of the third outgoing section (1.3) gradually increases, outward to the outlet of the duct, the width of the radial outlet for air increases smoothly from the hub area (2.2) to the outlet of the duct (1), forming a radial outlet for air between the outer surface of the conical partition ( 3) and the inner surface of the third outgoing section (1.3) of the duct (1). 2. The ventilation device according to claim 1, characterized in that the rounded surface of the conical partition (3) is formed on the basis of an arc of a circle and is part of a circular toroid. 3. The ventilation device according to claim 1, characterized in that the inner diameter D2 of the second cylindrical section (1.2) is larger than the inner diameter D1 of the first incoming cylindrical section (1.1), while at the boundary between the first incoming cylindrical section (1.1) and the second cylindrical section (1.2) forms a step of the inner surface of the duct (1), and the difference between the values of D1 and D2 is equal to the gap between the fan blade (2.1) of the fan (2) and the inner surface of the second cylindrical section (1.2). 4. The ventilation device according to claim 1, characterized in that between the maximum width of the fan blade (2.1) of the fan (2) and the inner surface of the second cylindrical section (1.2) of the duct (1) there is a minimum technologically permissible gap. 5. The ventilation device according to claim 1, characterized in that immediately before the hub (2.2) of the blade (2.1), in the direction of the air flow, a cowl (4) is fixed coaxially with the fan (2), which is a body of revolution with a conoidal surface obtained based on a curved convex generatrix with a base having a diameter corresponding to the diameter of the hub.

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