SU504861A1 - Device for regulating wind resistance of pneumatic structures - Google Patents

Description

FIELD OF THE INVENTION The invention relates to the operational equipment of genumatics facilities.

A device for regulating wind resistance of pneumatic structures, comprising a sensor for the velocity head of the wind, is known. It is connected through a regulator with electric motors of fans.

Experience in operating pneumatic structures shows that the overpressure in them largely depends on the quality of sealing. In case of various leakages (poorly closed entrance doors or gates, sealing defects in the supporting connector, etc.), much higher fan capacity is required to obtain the pressure required for these wind conditions, which cannot be achieved using a known device. . On the other hand, with a good hermetic marking of the structure, the pressure in it will be sufficiently high during normal operation of the fans and cp abatyvanga of the indicated device in case of wind increase will only lead to an excessive increase in pressure and discharge it through the limiting valve.

The goal of the art. Is to ensure the vetoustability of pneumatic coopv

depending on the wind speed at their various sealing.

The goal is achieved by the fact that it is mounted on an overpressure sensor in the building, the output of which is connected to a regulator made in the form of an electrocontact pressure gauge, whose pressure bend is connected with an additional tube to a velocity head wind sensor. The sensitive element of the sensor of the velocity head of the wind is made in the form of two convex plates facing each other vertically, and the section of the additional tube in height is made in the form of a pair ols.

FIG. 1 shows the proposed device, a general view; in fig. 2 - section venturi; in fig. 3 - electrocontact

New gauge in section with relay connection; in fig. 4 shows a basic control scheme for the power supply system. -

Device

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The signals to the electric motors of the fans 6 are supplied with electric power. By tube 7 from the sensor to the electrocontact manometer, it supplies, with an overpressure of air from the structure. The venturi tube is a construction of spherical surfaces: the bottom 8 and the top 9, fastened with studs 10 so that a smoothly tapering space is formed between them. In the narrowest place — at the center of the lower spherical surface — tube I. is installed. Wind flow of any horizontal direction falls between surfaces 8 and 9 and increases its speed, because the flow cross-section decreases. In the narrow place where the tube 11 is connected, a vacuum is created. The electrocontact manometer compares the overpressure of the building air and the dilution created by the wind pressure in the Venturi tube 1. The electrocontact manometer consists of two communicating elbows 12 and 13 filled with an electrically conductive fluid 14. In the pressure elbow 12, the tube 15 is coaxially fixed, which is connected vacuum zone in the tube and the sensor. Pressure leg 12 communicates with the internal volume of the structure with connecting tube 7. Pressure gauge 13 is open, i.e. it is associated with the atmosphere. Contacts 16 are installed in this elbow: the upper 17 and lower 18 contacts, which determine the working range of the first fan, and the upper 19 and lower 20 contacts, which determine the working zone of the second fan (the number of contacts and fans can be any).

The device works as follows.

In the absence of overpressure under the shell, the electrically conductive fluid in the pressure gauge is at the same level, the contacts 18, 19 and 17 of the pressure gauge are open, the relay circuit 21 and 22 are de-energized and the fans are opened by the contacts 23 and 24 are included in the work of filling the shell. With increasing pressure in the structure, the level of fluid in the knee 13 and the tube 15 rises. When the liquid level reaches contact 19, the relay circuit 22 closes, it is activated and disconnects the second fan with its contact 24.

Upon further raising of the fluid to pin 17, relay 2 is activated and switches off the first fan by pin 23. After operation, relays 21 and 22 are held in the on position by their contacts, respectively, 25 and 26. After switching off the fans, the pressure level in the building decreases, the fluid in the knee 13 of the pressure gauge is lowered. When its level drops below pin 18, relay 21 will disconnect and turn on the first fan. If the pressure in the structure continues - “to press, for example, because of the insufficient - shell (one fan is not - RESEARCH UNIT), then the level goes down even lower, opening contact 20; When this contact is open, the relay 22 is de-energized and the second fan is turned on.

The electrical contact pressure gauge can also be used as a signal sensor for changing the parameters of electro-angular devices, for example switching the number of pole pairs of the stator windings of multi-speed motors. The use of self-supporting chains of relays 21 and 22 by means of contacts 25 and 26, bypassing contacts 17 and 19 of the pressure gauge, reduces the number of relays. In the absence of wind, the first fan operates in periodic switching on in the pressure range determined by the position of the contacts 17 and 18 of the manometer. The second fan is connected at a deeper pressure drop in the structure and operates in the Rizb range. corresponding to the position of the contacts 19 and 20 gauge. When the wind appears in the tube 15, a vacuum is created that is proportional to the wind pressure, and a certain amount of gauge fluid is drawn into it, corresponding to the magnitude of the vacuum. Thus, at the same pressure Rshb in the construction of the fluid level in the knees 12 and 13 is reduced. Therefore, the inclusion of a second fan (or an increase in rotational speed) will occur earlier, and the disconnection will be later than in the absence of wind, and, consequently, the pressure in the structure will increase to the level required at a given wind speed.

The cross section of the manometer's knees may be taken unequally, for example, the section of the knee 13 is smaller than the knee 12 minus the cross-sectional area of the tube 15, so that the intervals between the contacts of the meter can be increased and the accuracy of work can be increased. The cross section of the tube 15 can be taken larger than the bend 12 (minus the cross section of the tube 15) to increase the influence of the vacuum on the wind gain, and the cross section of the tube 15 can be adopted with varying heights, for example, increasing along the parabola corresponding to the change in wind pressure from his speed.

Claims (3)

1. A device for controlling wind resistance of pneumatic structures, comprising a wind speed pressure sensor connected via a controller to fan electric motors, characterized in that it is equipped with an overpressure sensor to ensure wind resistance of a pneumatic structure depending on wind speed at various pressurization. air in the room, the outlet of which is connected to the regulator, made in the form of an electric contact meter, the pressure head of which with the help of The flax tube is connected to the sensor of the velocity head of the wind, made in the form of a Venturn tube. 2. A device according to claim 1, characterized in that the sensitive element of the sensor of the high-speed wind nanor is made in the form of two convex plates facing each other vertically. 3. The device according to p. 1, from l ich: a e with the fact that the section of the additional tube in height is made in the form of a parabola. - h HCG A, fi} eight / -7 /  2 Fi.Z Inclusion 2-so SehmuflpmOf} Q