DE244859C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JVi 244859 CLASS 42 /. GROUP

CARL A. HÄRTUNG in BERLIN.

Device for automatic gas analysis.

Patented in the German Empire on October 11, 1908.

Devices for automatic gas analysis are known in which the test gas from a. The measuring chamber is forced through an absorption vessel under pressure by means of a hydraulic pump, which is connected to the a liquid stop valve actuated by the hydraulic pump for escape of the gas residue is provided after registration by the diving bell.

ίο With such devices, a larger gas quantum than is later used for the analysis itself is intercepted or sucked into the same. Since changing pressures in the measuring space cannot be avoided here, an exact measurement is achieved by removing part of the excess gas by forcing it out of the measuring space. In order to achieve an exact measurement, the outlet openings are designed in such a way that they always offer the same resistance to the escaping gas. These known devices now require a special gas outlet which enables gas to be taken in or out. However, these special gas outlets complicate the measuring vessel and the entire apparatus, and because they can easily become leaky, they are also a source of operational malfunctions. In order to avoid these inconveniences, the arrangement is made in the present invention that - to save a special outlet for the excess gas in the first measuring chamber - the pipe of the valve mentioned is closed later than the gas suction pipe of the first measuring chamber, so that after the gas production through the absorber 45

tion vessel has already begun, an excess of the gas quantum trapped in the measuring space can escape through the absorbent before the start of the actual registration. But this will also brought about a further improvement. Until now, you had to use the pipe Make the shut-off valve as narrow as possible so as not to create too large a harmful space allow. Because after every gas analysis a gas residue remains here, which is with mixed with the new gas residue during the next analysis. For safe operability However, this is a very great disadvantage of the apparatus, because most of them are used in practice Analysis of the coming gases still lead to so many solid ones in spite of all the filtration facilities Contamination with itself that such narrow tubes, which are also through sticky Liquids are moistened, often clogged, causing complete malfunction will. In the arrangement on which the present invention is based, however the stagnant gas residue is driven out and eliminated with each analysis. Since the Connection path no longer forms a harmful space, its volume plays only a subordinate role, and instead of the previously used, Approximately capillary connections, tubes of 6 mm and more inner diameter can be used, without any at all noticeable error occurs in the analysis. Such a situation could possibly arise from that the absorption has to be determined before the start of the actual registration.

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side gas surplus would not proceed quickly enough. Incoming attempts but have shown that with the selected absorption device (bubbling through the gas through the absorption liquid and simultaneous surface absorption, which is still through Movement of the absorbent is assisted) the absorption occurs immediately.

The drawing represents the new device

ίο for example and schematically. When the liquid level in the measuring vessel a falls, which can be caused in any way (indicated in the drawing by the sink bottle b and hose connection c ), a gas sample is sucked in from the gas source by means of the pipe d. At the same time, the falling of the liquid level in the communicating vessel e connects the registration room f (registration diving bell) with the atmosphere through the pipes g, h , so that the gas residue from the analysis that has just ended can escape, the diving bell sinking back into its initial position . When the liquid level rises, the amount of gas sucked in is intercepted in the measuring space a under changing negative pressure by closing the confluence opening of the pipe d. As the barrier and driving fluid rise further, the amount of gas in α is compressed until it can overcome the fluid resistance in the absorption vessel i, on which it presses through the pipe connection k. Then the gas will begin to bubble through the absorption liquid, and since in the valve vessel e the absorption space, which is connected to the registration bell through the pipe path I , has not yet been sealed off from the atmosphere, the gas itself can stay there for so long under constant Pressure escape until the seal is closed by the further increasing barrier liquid in β . Since the resistance to be overcome in the absorption liquid i remains the same, each time e is closed, the liquid in the measuring vessel a will always have reached the same level. In the measuring space α , an equally large quantity of gas is always measured under the same pressure, if one disregards the fluctuations in the atmosphere, which can also be disregarded since they affect the registration space in the same way as the measuring space.

Claims (1)

Patent claim: Device for automatic gas analysis, in which the test gas is pressed by means of a pump through an absorption vessel which is provided with a valve controlled by the pump for the escape of the gas residue after the registration, characterized in that - around a special outlet for that in the first measuring chamber (a) To save excess gas - the pipe (g) of the valve mentioned is closed later by the pump than the gas suction pipe (d) of the measuring chamber (a), so that after the gas has already started to be conveyed through the absorption vessel, an excess of the in the measuring space (a) captured gas quantum can escape through the absorbent before the start of the actual registration. 1 sheet of drawings.