DE831990C - Apparatus for treating solutions with gases - Google Patents

Description

Apparatus for treating solutions with gases The invention relates refers to an apparatus for treating solutions with gases, e.g. B.

Sympathol, whereby <ler hydrogen so long in the circuit through the Liquid is pumped until the liquid is completely saturated.

At the moment one makes do with shakers, whereby one uses the hydrogen from a bottle into a vessel in which the liquid is and is pressure-tight. By shaking you only get one Surface contact, whereby the binding of the hydrogen with the liquid is very great is slow and cumbersome.

By the subject matter of the invention are all necessary Conditions met.

Imagine a vessel or a hollow sphere according to Fig. T with water filled. If you now send compressed air into this T Hohlikugcl at A, then After the famous Heron ball, squirt out the water at B. If you look now Place a gas in the hollow sphere and let in compressed air again at A, so at B a mixture of air and gas will flow out. Since now this mixture for If hydrogenation cannot be used, the gas is separated from the air by a septum C according to Fig. 2. This ScheidewZand C (Fig. 2) is as a hemisphere with a Flange made of raw rubber, which rests against the wall inside the hollow sphere. If you let in compressed air at A, this partition C will be pressed in, until it has reached the position of FIG. 3 and thus everything Gas that was present in room D (Fig. 2), expressed completely, Ida the partition C or rather membrane C to the inside of the wall of the hollow sphere through the Compressed air is firmly pressed and the space D has reduced to zero, so that no harmful space available can be. The higher the funding height of the gas, the higher the pressure of the compressed air must be; so you can Increase the gas delivery head at will, provided that compressed air is available Has.

In order to let this unit act as a pump, the compressed air inevitably controlled and at B as a pressure port a pressure valve and at E as Suction nozzle a suction valve installed (Fig. 4).

The pressure port B is connected to the nozzle F (Fig. 5), which in the vessel H, which is sealed in a pressure-tight manner, and the suction nozzle E is connected to the nozzle G of the vessel H, so that the unbound Amount of gas is sucked off again and again, or rather, flows off because in the vessel an overpressure must exist because the gas from a bottle with an overpressure in The entire unit has been let in and over and over again by the Pump is pushed into the liquid. The gas, which with the hydrogenation the liquid is bound, is drawn from a gas cylinder via a template N in the Suction line replaced from time to time.

In order to now achieve a continuous gas flow, which to avoid Crystallization of the nozzle F (Fig. 5) - is required, this unit is to be built up twice according to FIG. 4, so that a double-acting unit is obtained according to Fig. 6. The two partitions or membrane NEN C are rod through a dome J so connected that when sucked in on one side, on the is pressed on the other side. The coupling rod J ilst in two guide bushes K and through a stuffing box or Simmerrings to prevent the compressed air from escaping sealed.

The falling gas stream in the two dead camps is through a Air chamber L, which is provided with a pressure gauge and drain cock and in which both Feed pressure lines, balanced (Fig. 7).

The connecting piece M goes from the air chamber L to the nozzle F (Fig. 5), in which case a continuous gas flow is achieved.

The suction line E (Fig. 8) fetches the gas via a template N, which communicates through the connection piece 0 with the connection piece G (Fig. 5) in order to deposit to accomplish the entrained crystals of liquids. The template is equipped with a pressure gauge and a drain cock.

Fig. 9 shows the arrangement of the compressed air control. On the dome Rod J is an adjusting ring P, which is fixed by means of an adjusting screw. This Adjusting ring P moves the cams Qt ibzw at the end of the stroke. Q2 in the axial direction to the left or right, depending on the action of the compressed air, which then each on a control rod R1 and R2 are strongly connected to the control piston S and in the guide eyes T1 and T2 are stored. The control piston S moves suction in the control cylinder U, which is equipped with channels (Fig. Io).

The compressed air flows through the channel I position I (Fig. Io) above the Control piston S through channel 2 into the compressed air cylinder (Fig. II) position in the Space 3 and has already pushed piston 4 to the right in direction 5. Here is the air from the space 6 through the channel 2 'via the control piston S through the Exhaust duct 7 went outside (Filg. I0, position I).

After this operation of the piston 4 (Fig. Ii.

Position 1), the compressed air that has already been used flows out of the bladder left (Fig. 9 through the exhaust air pipe 1t, into the channel W1 (see Fig. 11, position 1) over the round slide coll) en 4 dul-cll the Xuspuizfkanal S-1 1 into the open. Simultaneously new compressed air flows into channel Y2 via the round slide piston 4 into the channel W2 through the compressed air tube V2 into the bladder on the right (Fig. G).

This causes the membrane C to break through in the bladder on the left and the bladder on the right the rigid connection with the coupling rod J (Fig. 9) in the axial direction to the right emotional. The adjusting ring P then pushes the cam Q2 before the end of the I lubes. with control rod R.2 and control piston 5 so far to the right until position II (Fig. Io) is reached.

Here, compressed air now enters the channel 1 'ül) Cr the control pistonS through the channel 2 'through a pipe Z2 into the space 6 and already has the piston 4 moved to the left in the cylinder in (position II) according to FIG.

In this position, compressed air now enters the channel Yj via the Piston 4 through channel W through tube Vt qn left the bladder and pushes the Membrane C in the bladder left and right through the connection I of the coupling rod J again to the left; the adjusting ring at the Eade of the stroke the cam Q1 with it the control rod Rt and control piston S to the left until position I (Fig. Io) is reached is. The compressed air flows through channel 1 (position I, Fig. Io) via the control piston S through channel II through the compressed air pipe Z, into the compressed air cylinder (Fig. 1 1, Position 1) into space 3 and has already pushed piston 4 to the right Direction 5. The game is repeated as long as compressed air can flow in.

Fig. I2: The compressed air is taken from a compressed air container, designed as a water separator and by a compressor, by means of a motor driven, mounted on the base plate of the unit, is fed. Man can also feed the container through a compressed air line.

On the compressed air sides of the two bubbles or hollow spheres are each one Faucet attached to the water, which flows in with the compressed air, from time to time to drain. The purpose of the two taps on the gas side is to keep the liquid entrained from time to time to vent from the gas space of the bladder.

The two pressure gauges on the compressed air line VX and V2 are used for Control of the compressed air. The compressed air and the gas pressure, which the pressure gauge is on the Gaswinidkessel L indicates, if the unit works economically be in the same amount. You can manually or with the help of a valve the compressed air automatically adjust to the required gas pressure so that no compressed air is lost.

For the apparatus to function properly, the pressure in the Gas air boiler and in template N must be at the same height. If the pressure in the gas air tank increases, so the pressure in the template falls, as the volume of gas in the whole unit including Vessel (Fig. 5) is constant as far as the gas binds with the liquid.

There is a phenomenon that the pressure in the gas air vessel rises and falls in the template, the unit can come to a standstill. This appearance can then be traced back to an over-crystallization in vessel H (Fig. 5), which you can then counter by increasing the compressed air while it is still is in the early stages. If this remains unsuccessful, of course, it is advisable to use the Remove the nozzle F from the vessel H (Fig. 5) and free it from the crystals.

Fig. 12 shows the complete assembly of the apparatus.

Claims (3)

PATENT CLAIMS: I. Apparatus for treating solutions with gases, characterized by the arrangement of two split hollow balls (Fig. 6) with inlet valves (E), Outlet valves (B) and compressed air connection (A), each with a hemispherical ball, flanged septum (C) made of rubber and one on the two septa attacking, moving in the axial direction through guide bushes with stuffing boxes Coupling rod (J). 2. Apparatus according to claim I, characterized by one of the Outlet valves (B) to a boiler (L, Fig. 7) leading pressure line and one of the gas inlet valves (E) to one with Vacuum manometer and drain cock provided template (N, Fig. 8) leading suction line. 3. Device according to claims I and 2, characterized by one fixed on the coupling rod (J) by means of a set screw, the cams (Qt and Q2) the control rod (R, R2) actuating the adjusting ring (P), one with the control rod connected control piston (see Fig. 10) in the control cylinder (U) for the purpose of automatic, alternating supply of compressed air via the compressed air nozzle (A) into the respective Hollow ball halves.