DE2340223B2 - CONDENSER PLUG - Google Patents

Description

The invention relates to a condensation trap according to the preamble of claim 1.

The functioning of such condensate pots with a bell float is based on the density difference between steam and condensate. If one assumes that the interior of the condensate pot is always a contains a certain amount of water, the bell float has depending on what proportions of Steam and condensate are in it, more or less buoyancy. When steam through the condensate inlet pipe enters the bell float, he is held inside the bell float, there this is sealed in the water. The low density of the steam leads to an increase in the buoyancy of the Bell float, which rises and thereby the valve on the upper wall of the interior of the Condensate trap operated so that the outlet opening for the condensate is closed. When condensate enters through the condensate inlet pipe, it fills the inside of the bell float due to its higher density, whereby the weight of the bell float is increased and it sinks in the water. Through this the valve controlling the outlet opening for the condensate is opened, so that condensate is discharged can be done from the condensate trap. If non-condensable gases reach the condensate trap, they escape through the gas outlet opening at the top of the bell float and collect in the upper area of the interior of the condensate pot, up to the outlet opening for the condensate of the condensate pot is opened. Then they are removed along with the condensate. Because the condensate inlet pipe is always connected to the system via a pipe where the steam and condensate can be drawn off the interior of the condensate trap is always under pressure. This helps drain the condensates when the outlet opening for the condensate from the condensate trap is opened

With the known condensate pots, however, between live steam and Aitdampf or relaxed Steam cannot be differentiated; rather, both types of steam cause the bell-shaped float to float and thus a closing of the valve closing the outlet opening for the condensate. The same thing applies when compressed air is fed into the condensation trap, since compressed air also has a lower density than that Has condensate

It is true that it is a generic condensate trap already known (US-PS 17 66 970), in parallel with the condensate inlet pipe, a discharge pipe for steam and to allow non-condensable gases to protrude upwards into the bell float. This exhaust pipe however, it opens down again into the inner chamber of a connector through a valve-controlled opening one to which the condensate inlet pipe is connected and can therefore at most be used for recirculation of air and the like, but not for their deposition.

The object on which the invention is based is therefore to provide a condensate trap of the type described To create a way that allows steam and non-condensable gases to be continuously withdrawn.

This object is achieved in the case of a condensate trap of the generic type according to the characterizing part of the claim 1 solved

The trap according to the invention has the advantage that, in addition to the normal functions of a trap an operational and functional improvement is offered by the fact that steam and condensates are separated and conducted in separate pipes, with the condensates to the boiler room and the withdrawn Steam can be recycled.

Furthermore, the condensation trap is prevented from closing due to old steam. The exhaust pipe for steam and non-condensable gases extracts this waste steam from inside the bell float before the Bell swimmer rises. Old steam represents only a small percentage of the total condensate flow However, this percentage can be sufficient to raise the bell float and the condensation trap to close if it was not withdrawn.

There are also non-condensable gases withdrawn from the interior of the system, which by the The condensation trap is emptied. Non-condensable gases, usually air and carbon dioxide, get dissolved in Water in the kettle. When the water evaporates, they are released together with the steam. However, when the vapor condenses, these gases do not redissolve and must be removed because they do not only do not transfer heat, but also form an insulating barrier for heat transfer. A conventional condensate trap cannot draw off these non-condensable gases satisfactorily. Through the with the condensation pot according to the invention possible continuous withdrawal of non-condensable gases you get a constant flow of steam and non-condensable gases even when the The outlet opening for the condensate of the condensate trap is closed. That means that something Live steam is drawn off before it can transfer its heat. The increase in performance of the The system compensates for this relatively small amount of steam

lust, however, far from.

Eventually, the speed of fluid supply to the trap is increased Da through the flue pipe for steam and non-condensable gases, steam and gases can be continuously withdrawn then a flow velocity is generated to the condensate trap Increased heat transfer, as a wiping effect occurs on the walls of the system to be emptied this stripping destroys the film of air and non-condensable gas destroying this Films increases the heat flow through the wall of the system.

Claim 2 describes a structurally compact design of the condensation plug according to the invention both the condensate inlet pipe and the exhaust pipe for steam and non-condensable gases are connected from a common connection piece to a conventional condensate trap 3 allows condensate that is entrained in the flue pipe or after deduction as fresh or Old steam is condensed to be recovered. Finally, claim 4 does not allow m: r recovery of steam, but also the series connection of condensation pots according to the invention in a steam line, namely each with condensate separation in the respective condensate trap.

The invention is explained in more detail using exemplary embodiments with the aid of the drawings

F i g. 1 in the cut a condensate pot with a bell float, which is equipped with an extraction device for steam and gases is provided, and

F i g. Fig. 2 shows a section of a condensate pot with different installation.

The condensation trap consists of a housing 11 with an interior 12 and has a lid 13 which is shaped like an inverted cup and attached to the Housing 11 is fastened by bolts inserted into bores 15 Outlet opening and a valve seat 17, the underside of which protrudes into the interior 12. The interior 12 contains a bell float 18 which has a hook 34 on its upper side and a lever 19 actuated with the valve closing body 20. The housing 11 has a concentric one in its lower part annular extension 21 with an internal thread 22 for

ίο the inclusion of a condensate inlet pipe 23, which protrudes vertically upwards into the bell float 18, but does not reach its top

A threaded nipple 24 is screwed into the internal thread 25 of the condensate inlet 26. A coupling 30 establishes a connection with its external thread to the connection piece 27 and with its internal thread to a discharge pipe 31 which protrudes over the upper end of the condensate inlet pipe 23 and almost reaches the top of the bell float 18. A deflector plate can be attached to the top of the discharge pipe 31 which prevents condensate from entering the drain pipe 31.

The end of the exhaust pipe 31, which can protrude from the coupling 30, as shown in FIG. 1 is shown Open into the atmosphere via an opening 32, or alternatively to a condensate discharge pipe or a be connected to another pipe, which collects the emitted steam and a further use supplies, or, as in FIG. 2 is shown, via a valve 36 to a condensate discharge pipe 33 or via a Valve to be passed into another pipe, which collects the withdrawn steam, and another Use.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Kohdenstopf with an interior in which a Bell float is arranged, which is associated with an outlet opening for the condensate Valve on the upper wall of the interior *. operated, which has a gas outlet hole on his Has top and in which a 'condensate inlet pipe and a discharge pipe for steam and not condensable gases protrude from below, characterized in that the exhaust pipe (31) upwards over the mouth of the condensate inlet pipe (23) to the vicinity of the inner Top of the bell float (18) and down from the housing (11) of the condensation pot is led out 2. iCondens pot according to claim 1, characterized characterized in that the exhaust pipe (31) coaxially within the condensate inlet pipe (23) with Distance to this and through the inner chamber (28) of a connecting piece (27) with which the Condensate inlet pipe (23) is connected 3. condenser according to claim 1 or 2, characterized in that the from the housing (U) of the Condensate drainage pipe (31) is connected to a condensate discharge pipe (33) 4. condenser according to claim 1 or 2, characterized in that the from the housing (11) of the Condensate plug led out exhaust pipe (31) is connected to a steam collecting pipe