DE426072C - Device for the automatic opening and closing of a gas, steam or air line in accordance with the pressure fluctuations occurring in a second line - Google Patents

Description

Device for the automatic opening and closing of a gas, steam or air line in accordance with the pressure fluctuations occurring in a second line. The invention relates to a device for automatically opening and closing a Gas, steam or air line depending on the one occurring in a second line Pressure fluctuations. The new thing is that there is a two-legged line in the first line Barrier liquid column, containing valve vessel is switched on, which is of a a two-legged column of liquid containing, connected to the second line and as a result of the rise or fall of the column of liquid in one of the legs rotating container is rotated so that according to the Pressure fluctuations in the flow of gas through the latter line Valve vessel is released or blocked by the barrier liquid.

The device is particularly suitable for use in gas analysis apparatus certainly. The line that can be opened or closed automatically is for example the gas supply line of the apparatus or a remote display line carrying air or gas; from the apparatus to a display or recording instrument located at a distance from it goes.

On the drawing the new device is in Fig. I and 2 in two Working positions in connection with some parts of a gas detection apparatus and in Fig. 3 in a position corresponding to Fig. i in connection with the complete apparatus shown. The one to be opened and the one to be closed Line a remote display line.

The valve vessel 2 and the container i sit next to each other firmly on a shaft 3 and are about their axis of rotation -. movable. The movement is limited on one side by a height-adjustable stop 5, against which an extension 6 connected to the movable system is pressed by a weight 7 that is also attached to the movable system. The line to be opened and closed consists of sections 13 and 14. Pipe sockets 15 and 1 6 are connected to the vessel 2, which are connected to the line sections by two thin hoses 9 and io that do not hinder the movement of the vessels i and: 2 13 and 14 are connected. The openings ii and 12 are used to fill the liquid in the vessels i and 2, e.g. B. mercury, and to connect the spaces 25 and 26 with the outside atmosphere. A pipe 17 standing on the vessel i is also connected by a thin hose 8 to a pipe 24 and the latter to a spherical space 22. A pipe 23 opens into the space 22 up to about its middle. Downward, the space 22 is connected through a pipe 2 i with a space ig filled with a liquid up to the mark 27. The space 28 above the liquid is connected by a pipe 2o to an intermittently operating compressed air generator 36 (see Fig. 3). Furthermore, a tube 30 protrudes into the tubes 23 and 21, the lower mouth 34 of which can be adjustable. The tube 3o serves to connect the absorption vessel 31 to the atmosphere at the appropriate time in order to allow the unabsorbed gas residues to escape.

The mode of operation of the new device in connection with the apparatus shown is as follows: The fresh gas to be examined is supplied through line 37, barrier; vessel 38 and line 39 into the measuring vessel 4o. The process water flowing from the pipe 42 into the box 43 first feeds the water jet pump 44, and further, after overflowing through the partition 45, the water supply tap 46. The pipe 46 'serves as an overflow. The process water flowing through the pipe 47 into the power station 36 closes the lower opening of the siphon pipe 48 and the pipe 47 when it rises in the power station 36. Then a certain amount of air is sealed off in the power station 36, which is compressed in the pipe 47 and in the siphon pipe 48 as the water column continues to rise.

The liquid in the ball 5o is pressed up in the measuring vessel 4o through the connecting pipe 2o, the excess gas being initially conveyed through the pipes 39 and 39 'into the atmosphere. After the gas has been brought to atmospheric pressure in this way, 50 ccm of gas are intercepted by the sealing liquid in the measuring vessel at the end of the inner tube 39 and pressed through the capillary 5 i through the potassium hydroxide solution in the absorption vessel 31. At the same time, the sealing liquid in the ball 19 has risen in the tube 2 i. The mouth 34 of the tube 3o is then immersed in the sealing liquid, so that the surface of the potassium hydroxide solution is sealed off from the external atmosphere. After the gases have been bubbled through the potassium hydroxide solution, the remaining unabsorbable constituents pass through the pipe 13 ′ into the space 52 and press the sealing liquid in the vessel 53 into the suction vessel 54.

By working with constant pressure water jet pump 44 is the air continuously through tube 55, aspirator 54, tube i3 ″ and tube 56 sucked. The pipe 55 is immersed in the vessel 54 as the barrier liquid rises further into the liquid. The climbing height of the latter is conditioned by the more or less large amount of absorbable constituents taken up by the potassium hydroxide solution. As a result, the in the pipe 5 5 entering and through the liquid in the Vessel 54 is opposed to a greater or lesser resistance to air bubbling through. In proportion to this resistance, the negative pressure falls or rises above the liquid in the vessel 54, line 13 ″ and 56 prevails.

If the liquid rises further in the pipe 21, the same arrives into the room 22 and closes the pipe 23, thereby the in the room 29 (Fig. 2), line 24, Hose 8, pipe 17 and space 32 located air compresses and causes the mercury in the container i to rash. The mercury column then rises higher in room 2 6. This results in a shift in equilibrium which are arranged on a common axis and oscillate freely around their center Vessels i and 2 take place, and they are rotated in the direction of the arrow x.

If the sealing liquid in the measuring vessel 4o reaches the capillary tube 51 (after pressing through the entire 5o ccm of gas), the pressure in the space 29, pipe 24, hose 8, pipe 17 and space 32 has risen so high, or the rotation of the freely oscillating Vessels i and 2 have become so large in the x direction that the tube 16 immersed in the mercury in space 33 is released. Then the percentage is CO. calibrated display or recording instrument 57 (vacuum gauge) through the long-distance line i 4, hose 9, pipe 16, space 33, pipe 15, hose io, pipe 13 with the line 13 "or 56 in connection and can on the prevailing in this In the meantime, the process water in the pipe 47 and the siphon pipe 48 has risen so far that when the siphon apex is reached, the water runs off through the pipe 48 'and the power plant 36 is siphoned out through the siphon pipe 48 and 48' all other liquids back to their previous level. The pressure prevailing in the space 29, tube 24, then also decreases, whereby the mercury in the vessels i and 2 also resumes its retirement and the latter also swing back to their original position is determined by the stops 5,. 6 the indicating and recording instrument 57 is then by the mercury lock on the pipe 1 6 of the tube 1 5 and 13 and of de The suction line 13 ″, 56 is shut off, and this shut off takes place before the sealing liquid in the measuring vessel 4o leaves the capillary 51. The display or recording instrument then remains at the imported value until the next analysis. With this facility: the displays of the individual analyzes are converted into a continuous curve, t. The respective percentage can therefore be read continuously on the display or registration instrument 57.

The unabsorbed gases occur after the opening of the mouth 34 of the Tube 3o through tube 23 into the atmosphere. When the tube 47 emerges the water in the power plant 36 as a result of the excavation; the interior of the vessel 36 reconnected with the atmosphere. When submerging the lower Opening the siphon pipe 48, the siphon sucks air with it, whereby the siphon water column rips off. When the barrier liquid falls in the measuring vessel 4o is through the pipe 37, Locking vessel 38 and tube 39 fresh gas has been sucked into the measuring vessel 4o, so that a new analysis can begin.

The valve vessel 2 and the adjusting vessel i can also each have a special Shaft can be arranged, each of the two vessels having a particular axis of rotation may have. The transfer of the movement of the control vessel to the valve vessel can then be done by any means.

Claims (1)

PATENT CLAIM: Device for the automatic opening and closing of a gas, steam or air line in accordance with the pressure fluctuations occurring in a second line, characterized in that a valve vessel (2 ) is switched on, which is rotated by a two-legged column of liquid, connected to the second line (24) and rotating as a result of the rise or fall of the liquid column in one of the legs, so that according to the in the latter line (24 ) occurring pressure fluctuations the flow of the gas through the valve vessel (2) is released or blocked by the barrier liquid.