RU2295094C1 - System for final humidification of air in room - Google Patents

Abstract

FIELD: creating of comfort conditions and microclimate in industrial rooms.

SUBSTANCE: proposed system consists of pneumatic injectors, pipe lines for supply of water and compressed air to these injectors and pneumatic injector control unit. Pneumatic injector has body with hole for delivery of compressed air from main; upper part of body is provided with guide member with wedge-shaped point made in two diametral directions. Cap engageable with body has upper and lower cavities communicated with at least two pairs of diametral slots having width "b" and heights "h₁" and "h₂" for escape of air and water, respectively; b is width of these slots.

EFFECT: enhanced efficiency and reliability of pneumatic spraying of water.

3 cl, 3 dwg

Description

The invention relates to techniques for air conditioning and can be used to create comfortable microclimate conditions in industrial premises, in particular as local dampening systems.

The closest technical solution to the claimed object is a system according to the patent of the Russian Federation No. 2067730, class. F 24 F 3/06 of 10/10/96 containing a spray gun and a control unit.

Its disadvantage is the relatively low efficiency of the pneumatic spraying process.

The technical result is an increase in the efficiency and reliability of the process of pneumatic spraying of water.

This is achieved by the fact that in the air after-humidification system consisting of pneumatic nozzles, piping networks used to supply water and compressed air to them, and a pneumatic nozzle control unit, the pneumatic nozzle contains a housing in which a hole is made for supplying compressed air from the main moreover, a guide element with a wedge-shaped tip made in at least two diametrical directions is installed in the upper part of the housing, and a cap having an upper and zhnyuyu cavity connected with at least two pairs of diametric slots having a width «b» and height «h _1" and «h _2", wherein the upper cavity is connected with the water supply fitting, which holds the orifice diameter «d», and the pneumatic nozzle operation control unit contains a hair moisture regulator, membrane valves, shut-off valves, a needle throttle for regulating the pressure of compressed air in front of the membrane valves, a voltage transformer, control lamps, a switch and an electro-pneumatic relay , Whereby the compressed air nozzle is made with the following ratios of the dimensions of its basic elements, which is in the optimal range of values: N / V = 2.5; b / B = 0.2 ... 0.3; D ₁ / D ₂ = 1.3 ... 1.5; d / D ₂ = 0.5; h ₂ / h ₁ = 1.2 ... 2.5; D ₃ / D ₁ = 5.0 ... 7.0; Where:

H is the height of the nozzle housing assembly, B is the width of the wedge-shaped tip assembly from two sides; d is the diameter of the calibrated hole of the nozzle for supplying water, D ₁ is the diameter of the hole in the housing for supplying compressed air, D ₂ is the diameter of the hole in the nozzle for supplying water. D ₃ - the diameter of the upper and lower cavities formed by the body and cap, h ₁ and h ₂ - respectively, the height of the slots for the flow of air and water, b - the width of these slots.

Figure 1 shows the frontal section of the pneumatic nozzle of the humidification system, figure 2 presents the profile projection of the pneumatic nozzle of the humidification system, figure 3 - control unit for the operation of pneumatic nozzles.

Pneumatic dampening systems consist of nozzles (FIGS. 1, 2), piping networks used to supply water and compressed air to them, and a control unit for the operation of pneumatic nozzles (FIG. 3). In addition, there are safety devices that exclude the possibility of pouring water from the nozzles upon stopping the supply of compressed air to them.

The pneumatic nozzle (figures 1 and 2) consists of a housing 1 with a height of "N", in which a hole 2 with a diameter of "D ₁ " is made for supplying compressed air from the main. In the upper part of the housing there is a guide element 3 with a wedge-shaped tip 5, made at least in diametrical directions. The width of the wedge-shaped tip 5 assembled on both sides is "B". With the housing 1 interacts with a cap 6 having an upper 7 with a diameter of "D ₃ " and a lower 8 with a diameter of "D ₃ " cavity. In addition, at least two pairs of diametrical slots 4 are made in it, having a width of "b" and a height of "h ₁ " and "h ₂ " connected respectively to the cavities 7 and 8. The upper cavity 7 is connected to the water supply fitting 9, in which made a hole 10 with a diameter of "D ₂ " and a calibrated hole 11 with a diameter of "d". For fastening the cap 6 on the housing 2 and attaching the fitting for supplying air from the line, nuts 12 are used.

Figure 3 presents the control unit of the pneumatic nozzles. It contains a hair moisture regulator 15, diaphragm valves 14 and 17, shut-off valves 13, a needle throttle 16 for regulating the pressure of compressed air in front of the diaphragm valves, a voltage transformer 18, control lamps 19 and 22, a switch 21 and an electro-pneumatic relay 20.

The humidification system operates as follows.

Pneumatic nozzle operates as follows.

Compressed air from the line enters the channel 2, passes into the lower cavity 8 of the cap 6 and through two diametrically opposite slots 4 having a width of "b" and a height of "h ₁ " and "h ₂ " respectively, goes into the room. Water, having passed a calibrated hole 11 with a diameter of "d" in the nozzle 9, enters the upper cavity 7 of the cap 6 and leaves two nozzles with a height of "h ₂ " located above the slots for the outlet of compressed air "h ₁ ". When exiting the nozzle, water meets a stream of compressed air and is sprayed onto the smallest particles. Water and compressed air at the outlet of the nozzle fall on the wedge-shaped tip 5, where the compressed air has a maximum speed; thanks to which the energy of compressed air is used most efficiently. The optimum pressure of compressed air in front of the nozzle is 0.9 ... 1.1 ati, and the water pressure should be within 0.1 ... 0.2 ati. Under these conditions, the nozzle capacity is about 5 l / h with an air flow rate of approximately 3.5 m ³ / h. Pneumatic nozzles are widely used both in new textile mills and in old factories.

For optimal operation and reduction of energy consumption, the pneumatic nozzle is made with the following size ratios of its main elements, which are in the optimal range of values: N / V = 2.5; b / B = 0.2 ... 0.3; D ₁ / D ₂ = 1.3 ... 1.5; d / D ₂ = 0.5; h ₂ / h ₁ = 1.2 ... 2.5; D ₃ / D ₁ = 5.0 ... 7.0; where: N is the height of the nozzle housing assembly, B is the width of the wedge-shaped tip assembly on both sides; d is the diameter of the calibrated hole of the nozzle for supplying water, D ₁ is the diameter of the hole in the case for supplying compressed air, D ₂ is the diameter of the hole in the nozzle for supplying water, D ₃ is the diameter of the upper and lower cavities formed by the body and cap; h ₁ and h ₂ - respectively, the height of the slots for the outflow of air and water, b - the width of these cracks.

The control unit of the pneumatic nozzles (figure 3) works as follows. When supplying compressed air to the cavity above the membranes of valves 14 and 17, the supply of compressed air and then water is first opened. After turning off the compressed air supply, the valves close in the reverse order; this protects against the risk of leakage of unsprayed water in the pipes through the nozzles. The described safety device is also used to automatically control the operation of the nozzles, which is carried out using a humidity controller 15 acting on an electro-pneumatic relay (electromagnetic valve) 20 mounted above the membrane valve 14 located on the water supply line. This relay, depending on whether the electric current is turned on or off, opens or closes a narrow hole in the valve cover 14, opening or closing the air outlet under the membrane to the atmosphere. At the same time, the pressure on the corresponding membranes changes, and consequently, the supply of water and compressed air to the nozzles. In some cases, each membrane valve has its own electro-pneumatic relay, which is switched on via an independent time relay. The electro-pneumatic relays are adjusted so that the water supply is turned off 10 seconds before the compressed air supply is cut off, and turned on 10 seconds later than the resumed air supply.

Claims (3)

1. The air humidification system, consisting of pneumatic nozzles, piping networks used to supply water and compressed air to them, and a pneumatic nozzle control unit, characterized in that the pneumatic nozzle comprises a housing in which a hole for supplying compressed air from the main moreover, a guide element with a wedge-shaped tip made in at least two diametrical directions is installed in the upper part of the housing, and a cap having an upper and lower interacts with the housing io cavities connected to at least two pairs of diametrical slots having a width of "b" and a height of "h ₁ " and "h ₂ ", the upper cavity being connected to a water supply fitting in which a calibrated hole with a diameter of "d" is made. 2. The air humidification system according to claim 1, characterized in that the pneumatic nozzle operation control unit comprises a hair moisture regulator, membrane valves, shut-off valves, a needle throttle for regulating the pressure of compressed air in front of the membrane valves, a voltage transformer, control lamps, a switch and an electro-pneumatic relay. 3. The air humidification system according to claim 1, characterized in that the pneumatic nozzle is made with the following size ratios of its main elements, which are in the optimal range of values: H / B = 2.5; b / B = 0.2-0.3; D ₁ / D ₂ = 1.3-1.5; d / D ₂ = 0.5; h ₂ / h ₁ = 1.2-2.5; D ₃ / D ₁ = 5.0-7.0, where H is the height of the nozzle assembly assembly; In - the width of the wedge-shaped tip assembly from two sides; d is the diameter of the calibrated hole of the nozzle for supplying water; D ₁ - the diameter of the holes in the housing for supplying compressed air; D _{2 is the} diameter of the hole in the nozzle for supplying water; D ₃ - the diameter of the upper and lower cavities formed by the body and cap; h ₁ and h ₂ - respectively, the height of the slots for the flow of air and water; b is the width of these slots.

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