RU112357U1 - SELF-ADJUSTABLE MECHANICAL VENTILATION NETWORK - Google Patents

Abstract

Self-regulating mechanical ventilation network with automatic air flow control, containing a device for intake of outside air, a fan, an air distributor, a device for controlling the flow of air supplied, a tee, a main branch, characterized in that it has a self-adjusting gas-dynamic air flow regulator, which, depending on the size and direction of the resulting aerodynamic moment a change in the degree of overlap of the "living" section of the air duct in the branch of the tee, planted on the axis, of the weather vane, fixed on the axis so that when it turns, the axisymmetric rotary sector rigidly connected to it overlaps the passage openings of the axisymmetric fixed sector rigidly fixed to the walls of the tee, an impeller and a diffuser that automatically regulates the air flow in the branch line.

Description

The utility model relates to the field of mechanical ventilation of forced type, namely to devices for automatically controlling air flow.

The purpose of the invention is to automatically control the air flow during operation of the mechanical ventilation network through the use of a self-adjusting gas-dynamic air flow controller.

Manual configuration of devices for controlling the flow rate of the supplied air into the main branch of the ventilation network requires the participation of qualified specialists and appropriate tooling.

Automatic control implies the installation of additional automation elements (servos, flow sensors, automation system).

Of the above setup methods, in the first case, organizational problems arise, and in the second case, significant capital investments are required.

Therefore, instead of existing devices and methods for regulating air flow, a self-adjusting gas-dynamic air flow regulator is proposed, the principle of which is based on the characteristics of the distribution of air flows in the tee.

The essence of the invention: during the operation of the ventilation network there is a need to control the amount of air supplied in the room. The schematic diagram of the air supply to the premises is shown in figure 1. The schematic diagram contains: 1 - a device for intake of outdoor air; 2 - fan; 3 - air distributor; 4 - served premises; 5 - device for controlling the flow rate of the supplied air; 6 - tee; 7 - trunk branch; 8 - branch In this case, devices are used, the adjustment of which is done manually or by automatic regulation [1].

A self-adjusting gas-dynamic air flow regulator, a schematic diagram of which is shown in figure 2. Depending on the size and direction of the resulting aerodynamic moment, the degree of overlap of the "live" section of the duct in the tee branch changes and thereby automatically adjusts the air flow in the branch.

In the tee - 1 on the axis - 2 are fixed: the weather vane - 3, the impeller - 4 and the axisymmetric rotary sector - 5. The axisymmetric fixed sector - 6 is rigidly fixed to the walls of the tee - 1. Axis - 2 is fixed on 2 plain bearings - 9 which are located in the wall of the tee - 1 and in the axisymmetric fixed sector - 6. The weather vane - 3 is fixed on the axis so that when it is rotated, the axisymmetric rotary sector - 5 rigidly connected with it overlaps the passage holes of the axisymmetric fixed sector - 6, which reduces live "section To pass the air flow in the branch - 8. Diffuser - 7 is mounted on a branch of the tee, so the air flow in the branch is always less than in the backbone.

A fragment of the duct with a self-adjusting gas-dynamic air flow controller is shown in figure 3, and the design of the device is shown in figure 4.

The claimed effect of the self-adjusting gas-dynamic air flow controller is as follows.

According to the scheme of air movement (see figure 5), the gas vane will be affected by the gas-dynamic force, determined by the dependence:

Where - mid-section of the wind vane plate; φ is the shape factor of the weather vane; ρ is the air density; υ ₂ - air velocity.

The mid-sectional area in the considered scheme depends on the angle of rotation of the plate (weather vane) β (see figure 5). With increasing angle β increases accordingly, the strength of N ₂ increases.

The weather vane - 3, placed in the air stream, under the action of the force N ₂ will tend to turn in the direction of flow.

Thus, the resulting force N ₂ , multiplied by the shoulder (the distance from the axis of rotation to the center of application of force), creates a torque M ₂ , which is transmitted to the axis - 2, rigidly connected to the wind vane - 3 (see figure 2), and further on the axisymmetric rotary sector - 5. The rotation of the sector - 5, relative to the fixed sector - 6, partially overlaps the cross section for the air flow in the branch - 8. To counteract the torque M _{2, the} impeller - 4, which represents set at an angle to the flow axis of the formation us and deployed toward providing torque occurrence of M _3, M ₂ opposite point.

The set of moments M ₂ and M ₃ gives the resulting moment, which determines the angle of rotation of the axis - 2 and sector - 5. Depending on the angle of rotation of the sector - 5, the cross-sectional area for the passage of air in the branch and, accordingly, the air flow changes.

Thus, a change in air flow in the main direction of the ducts leads to a change in the air velocity in the tee and a change in the values of the moments M ₂ and M ₃ .

Depending on the magnitude and direction of the resulting moment, the degree of overlap of the “live” section in the tee branch changes, thereby automatically providing an adjustable air flow rate and, therefore, self-regulating operation of the mechanical ventilation system.

The experimental setup shown in figure 6 (a, b), successfully passed the test and confirmed its performance. Literature:

1. Blumenkrants B.A. and other reference book of the installer. Installation of ventilation systems / under. ed. Staroverova I.G. Vol. 3, revised. - M.: Stroyizdat, 19778.- 591 p.

Claims (1)

A self-regulating mechanical ventilation network with automatic air flow control, comprising an external air intake device, a fan, an air distributor, a supply air flow control device, a tee, a main branch, characterized in that it has a self-adjusting gas-dynamic air flow regulator, depending on the size and direction the resulting aerodynamic moment, the change in the degree of overlap of the "live" section of the duct in the branch a tee, mounted on an axis, a weather vane fixed on the axis so that when it is rotated, an axisymmetric rotary sector rigidly connected with it overlaps the passage holes of the axisymmetric fixed sector, rigidly fixed to the walls of the tee, impeller and diffuser, which automatically regulates the air flow in the branch of the highway.