SU806044A2 - Hydraulic lock-fire trap - Google Patents

Description

(54) PUMP REMOVER

The invention relates to fire fighting equipment, and more specifically to safety devices, and can be used in gas, metallurgical and chemical protection equipment (equipment from spreading flame from pipelines beyond 1) at the formation of highly hazardous gas mixtures. According to the main author. St. By 585853, a fire trap is known; it has forced gas transmission and is able, without interrupting its work, to maintain a predetermined residual pressure in the receiving gas chamber when gas supply to the equipment is stopped. The hydraelectric chamber contains a fluid filled to the overflow plug Ktqmyc, a water seal threshold that divides the gas space of the housing into a receiving chamber with a patra & gas inlet and outlet chamber with gas outlet nozzle, fluid outlet nozzle and inclined hydraulic nozzles (overflow threshold t above the fire). The disadvantage of the hydraulic air cooler is a significant increase in pressure in the zone before the central air release as the gas flows to it the most calculated, which makes possible the leakage of gas through the leakage of the protected equipment. This reduces the reliability of the fire protection device. The purpose of the invention is to increase the reliability of fire blocking The reduction of gas pressure in the fi lm chamber of the hydraulic seal is achieved. The goal is achieved by having the hydraulic nozzles coaxially mounted on their ends with an oblique lower open cut parallel to the liquid level, and the nozzle cut is placed at the cut of the nozzle. fire trap. Fire trap air trap contains a fluid filled up to the overflow threshold 1 body 2; the threshold 3 water seal that divides the gas space of the body into the receiving chamber 4 with the inlet 5 yes vyhod1ogyu gas chamber 6 with nozzle 7 gas outlet; liquid outlet nozzle 8 and inclined hydraulic nozzles 9 with nozzles 10. The lower section of the nozzle (nozzles) is buried under the level of the overflow threshold 1 by the value of the specified residual pressure corresponding to the liquid column H, which must be kept in the inlet 4 to in the equipment to be protected; even if the gas supply to the equipment is completely cut off and, consequently, to the water seal.

The nozzle with the nozzle works as follows.

In the absence of gas and jet. The fluid in chambers 4 and 6 is at the same level; part of the nozzle is filled with liquid. When applying the jet. The jet captures the gas in the nozzle, brings it beyond the threshold along arrow A and the nozzle cavity is completely filled with liquid. In view of the fact that the nozzle cut is recessed to a depth H, further transfer of ria3a is impossible.

At insignificant supply of gas. The level in chamber 4 is lowered to the point where the nozzle is cut off, the gas enters the jet under the nozzle and is immediately ejected beyond the threshold in arrow B. Since the gas is low and trapped in the cross section fj at a distance from the nozzle section corresponding to then the flow of gas under the nozzle cut is constantly ahead of the jet's flow rate along its drift, and the nozzle cut is constantly submerged again with the cessation of gas supply to the jet.

With a constant (or rapid) increase in gas flow to the highest estimated. The gap between the nozzle cut and the liquid increases by the amount AHj necessary to pass the gas to the jet, and the jet begins to work with the highest capacity for gas capture and transfer beyond threshold 3.

Upon termination of gas supply to the water seal. The working jet lowers the pressure in chamber 4, the level rising by the amount AHi undermines the nozzle cut and blocks the flow of gas to the jet) the jet ejects the remaining gas from the nozzle and the nozzle is filled with liquid. The gas transfer stops in the chamber 4, and therefore in the backfill equipment, the specified residual pressure is maintained. Consequently, both with a small and with the greatest gas supply, it is captured by a jet at a distance from the nozzle section, corresponding to its highest gas capture and transfer capacity, i.e. practically on one and

same level. The jet itself is always provided with the possibility of the greatest productivity, which is realized only when the gas is completely supplied to the hydraulic seal, and with a small supply it is constantly blocked by flooding the nozzle edge, since in this case the possibility of a jet over the gas ablation is higher than its flow under the cut. nozzles

Formula inventions

Fire trap auth. St. No. 585853, differing in the fact that, in order to increase the reliability of fire protection equipment by reducing the pressure of gases in the zone of the receiving trap, hydraulic nozzles have coaxial nozzles installed at their ends with an oblique lower open cut parallel to the liquid level, and the nozzle cut is placed above the cut nozzles

Sources of information taken into account in the examination

1. USSR author's certificate No. 585853, cl. 2 A 6.2 C 4/00, 1975.

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Claims (1)

₂₅ claims Water trap fire extinguisher according to ed. St. No. 585853, characterized in that, with the aim of increasing the reliability of the ₃ θ-type fire barrier by reducing the pressure of the gases in the area of the water trap receiving chamber, the hydraulic nozzles are coaxially mounted at their ends with an oblique lower open cut parallel to the liquid level, and the nozzle cut placed above the nozzle cut 35 ki.