DE3603978A1 - CONDENSATE DISCHARGE - Google Patents

Description

The invention relates to a steam trap with an annular space having guide surfaces between a hollow cylindrical partition and a housing in which the annular space and the interior of the partition is in communication with an inlet, an outlet and an outlet valve.

U condensate drains of this type are known and are used to divert condensate water in gas, for example compressed air and steam lines, preferably under the influence of the centrifugal force which becomes effective when the fluid rotates outward.

With such condensate drains working with centrifugal force the gas rotates in the upper part of a case and water droplets become water droplets under the influence of centrifugal force thrown outwards and separated in this way. The gas then arrives at an outlet, while the a separated water droplets are led to the outside via an outlet valve in the lower part of the trap housing.

Conventional steam traps have a hollow cylindrical partition in the upper part of their housing and accordingly an annular space between the partition and the housing wall. In this annulus there are guide surfaces while the ring and the interior of the hollow cylinder with an inlet, an outlet and an outlet valve in connection stand. Accordingly, the gas flowing in through the inlet is set in rotation in the annular space, so that the water droplets be thrown outwards under the influence of centrifugal force. The drops of water separated out in this way flow down and are via the outlet valve

derived. In the center of the rotational flow, the gas reaches the outlet via the interior of the hollow cylindrical partition of the separator.

However, it has been found that the conventional With condensate drains, the water droplets are only partially centrifuged out, even with strong rotation accordingly the degree of condensate separation is limited.

The reason for this is the fact that the condensate discharge only results from the gas rotation The laws of nature follow, and accordingly the gas under the influence of centrifugal force more or less depending on its mass migrates towards the periphery, so that very small water droplets migrate from the outside inwards along the surface and thus fed to the separator outlet together with the gas.

; The invention is therefore based on the object of the degree to improve the condensate separation in a separator of the type in question.

The solution to this problem is based on the idea of catching water droplets and positively hurling them outwards; it consists in the fact that in a condensate drain of the type mentioned at the beginning on the outside of the partition cylinder Inclined ribs and extending from their upper ends to their lower ends, stepped in partition walls at the lower ends of the inclined ribs transitional spiral ribs are arranged.

Accordingly, in a steam trap according to the invention, the inclined downwardly inclined ribs run in the ring

space between the partition cylinder and the housing wall, so that the direction of movement of the gas as it flows through the annular space is adjusted according to the inclined rib course. As a result, the gas rotates in the annulus due to its continuity and there is also a rotation above and below the bevel ribs. The gas thus enters the annular space in a rotating manner, which it also rotates leaves again. Because the spiral ribs, inclined outwards, between the upper and the lower ends of the inclined ribs run, the gas moves further outwards than corresponds to the tangentials to the annulus, and is in a more favorable state moves against the inner wall of the separator housing. Since also the width of the annulus along the Inclined ribs decreases from top to bottom, the speed of rotation increases accordingly and reaches at the bottom At the end of the inclined ribs their highest value.

Finally, the gradual transition of the spiral ribs into the radial partition walls leads to the end of the inclined ribs a sudden expansion of the annulus in the area of the partition walls. Because of the rotation of the gas, this results in a Pressure drop in the area of the partition walls, due to which the water droplets adhering to the adjacent surfaces collect at the connecting edges between the spiral ribs and the partition walls of which they are due to the strong rotational flow or the maximum flow velocity established here and against the inner wall the separator housing.

It is particularly advantageous in the steam trap according to the invention that the separation of gas and water not only on the centrifugal force resulting from the gas rotation

fugal force is based, but the water droplets on the edges between the spiral ribs and the partition walls are positive are merged and the rotation speed reaches its maximum just at these edges, so that the Drops of water are blown away from the edges and against the inner wall of the arrester housing. From this it follows an extremely high degree of separation.

This is not only based on an increase in the speed of rotation, but also on the fact that the width of the Annular space at the end of the inclined ribs reaches its minimum and, accordingly, the speed of rotation in the most important Zone, i.e. at the end of the inclined ribs, is greatest. As a result, the rotation speed is critical on both sides Edges relatively small, so that the water droplets are not sucked off together with the gas in the outlet direction or the water surface at the outlet valve and thus its function is disturbed.

Special advantages, in particular a high degree of separation, result if the hollow cylindrical ones are on the outside Partition wall are arranged from the upper ends of the inclined ribs upwardly extending longitudinal ribs and accordingly the gas entering the annular space hits the longitudinal ribs during its rotational movement, so that the Water droplets partially hit the longitudinal ribs and stick and are thus separated from the gas will.

Has at least one outer surface of the partition, to which the inclined and spiral ribs also belong, a certain amount Roughness like a pear skin, then the water droplets adhere more easily to this surface and result

some reduction in the speed of rotation of the gas in the vicinity of the surface in question, which makes it possible to capture the water droplets on the surface. Those deposited in this way on the surface Water droplets collect on the above-mentioned connecting edges and are against the inner surface of the Blown arrester housing. Thus, water droplets can be separated from the gas by adhering to the rough surface.

If the lower part of the partition wall cylinder gradually widens to approach the housing wall, it increases in this area the speed of rotation of the gas and is thereby further separated as well as against water blown the inner surface of the separator housing. In this case, the angle of inclination should be the funnel-shaped Cylinder opening, based on the vertical, be 25 to 30 ° and 35 for an optimal result.

The invention is explained in more detail below with reference to an exemplary embodiment shown in the drawing. In the drawing show:

1 shows a vertical section through a steam trap according to the invention with a reducing valve,

2 shows a vertical section through a valve seat,

Fig. 3 shows a cross section along the line III-III in Fig. 2 and

4 shows a perspective illustration of a partition wall cylinder.

The steam trap A according to the invention is an integral part of a reducing valve B for a steam line educated.

The reducing valve consists of a spring housing 2 containing a pressure adjusting spring 1 and a guide valve 3 containing valve housing 4, a flange piece 6 containing a main valve 5, a separation chamber 7 in a separator housing 8 and a bottom cover 9 each made of a cast material.

Between the spring housing 2 and the valve housing 4 is a thin metal plate 10 clamped as a diaphragm.

The lower end of the pressure adjusting spring 1 is upside down the diaphragm plate connected by means of a disk 11, while the underside of the diaphragm disk 10 with the top of a cap 13 at the end of a valve rod 12 of the guide valve 3 is in connection. The one above the Diaphragm disc 10 located valve chamber is via a passage 14 with the atmosphere in connection, while the space located below the diaphragm disk 10 is connected to an outlet channel 23 via a passage 15 is.

A set screw 17 extends through a stainless steel bearing piece 16 and is secured with the aid of a lock nut 18 secured against rotation; at its free end it holds a steel ball 20 in a shoe 19 at the upper end of the pressure adjustment spring 1.

The outer end of the adjusting screw 17 is protected with the aid of a cap 21 screwed onto the spring housing 2 .

The flange piece 6 has an inlet channel 22 and an outlet channel 23 with a horizontal partition, in which is screwed into a valve seat with a valve opening. The main valve is located below the valve opening 25 5, the valve body of which is held in the valve seat by means of a helical spring. At the top is the Valve body with a piston 26 in connection.

The guide valve 3 is located between a channel 27 leading to the inlet channel 22 on the one hand and one to one Space above the piston 27 leading through passage 28; it consists of a valve seat 29 extending valve rod 12 and arranged at the lower end of the valve rod, upwardly spring-loaded valve piece 30. In the passage 27, a sieve 31 is arranged.

The piston 26 slides in a cylinder 32 inside the flange piece 6; it has two peripheral annular grooves, in which have springs and piston rings made of polytetrafluoroethylene. The piston 26 also has an opening 33 that connects the upper and lower sides of the piston and the outflow of a certain amount of gas from the top of the Piston and thus a certain pressure control.

The main valve 5 is a double cylinder 34 from a straight outer cylinder and a longer one in the upper and in the lower part diverging or widening in a funnel shape

Surrounding terning inner cylinder. Outside the double cylinder 34 there is a sieve 35, while in the cylinder axis a guide sleeve 36 connected to the cylinder for a guide sleeve 36 connected to the valve plate of the main valve 5 Guide rod is arranged. The inlet channel 22 stands above the screen 35 with an annular space 37 between the two Cylinder jackets in connection, while the interior of the double cylinder 34 via the valve opening 25 of the main valve is connected to the outlet channel 23.

In the annular space 37 there are guide surfaces 38 connected to the double cylinder. The double cylinder 34 with its Guide surfaces 38 are made of precision casting and have a surface roughness in the area of the inflowing gas such as a pear peel; it can also be used by other casting processes or by machining as long as at least the outer surface is sufficiently rough.

For a product manufactured by the lost wax double cylinder, the surface roughness is about 15 to 50 _m at maximum roughness depth R of Japanese INDU-

Max

Strienorm JIS (B 0601). If the surface is sufficiently rough, i.e. a surface roughness of at least 10 R

Max

there is a good separating effect with regard to the separation of condensate. Those cylinder surfaces that have a roughness roughly like a pear skin should have, are marked with C in FIGS. 2 and 3.

As can be seen from the enlarged representations of FIGS. 2 to 4, the guide surfaces 38 each consist of one of the the upper part of the inner cylinder protruding and extending up to the outer cylinder longitudinal rib 39, a directly subsequent inclined rib 40 running between the outer and inner cylinder, as well as one extending from the upper

side of the inclined rib 40 extending, spirally from Inner to outer cylinder extending spiral rib 41. The spiral rib 41 is inclined so that in the Top view of FIG. 4 results in an approximately wedge-shaped or sickle-shaped surface of the inclined rib 40. The lower end of the Spiral rib 41 is connected to a radial partition 42 to form a step. In the annulus between the two cylinders are a total of five guide surfaces 38 of this type.

The lower part of the inner cylinder widens in a funnel shape and ends at a predetermined distance from the inner wall of the outer cylinder; its included angle θ with respect to the vertical is 35 ° and is with respect to a good separating effect at 25 to 50 °.

The lower valve cover 9 is connected and limited to the lower end of the Ablextergehäuses 8 via screw bolts the separation chamber 7 with a spherical float valve 43.

In the cover 9 there is an outlet valve seat 44 on the Inside of an outlet opening 45. The float ball 43 is located inside a catch cap 46 with a lower one Opening 47. There are ventilation openings in the catch cap 46 48.

A gas entering via the inlet channel 22 is set in rotation with the aid of the inclined ribs 40 in order to be entrained Separate water droplets and centrifuge them out. The longitudinal ribs 39 direct the gas flowing in vertically the rotational current caused by the inclined ribs 40 and

cause a decrease in the speed of the rotational current and direct it more downwards. This is where they meet Drops of water partially on the longitudinal ribs 39 and adhere there.

The spiral ribs 41 conduct the rotational current further outwards than corresponds to the tangential direction of the annular space 37. At the lower end of the inclined ribs 40, the annular space width reaches its minimum and the flow velocity their maximum. Since the lower ends of the spiral ribs 41 are stepped with the radial intermediate walls or inclined rib ends are connected, the width of the annular space 37 increases suddenly at the connecting edge between the Spiral ribs 41 and the partition walls 42 as a limit. As a result, a pressure decrease occurs here during the rotation of the fluid and the water droplets adhering to the rib surface collect at the connecting edges. the collecting water droplets are away from the connecting edges by the strong rotational current and against the Blown inner wall of the arrester housing 8 including the inner wall of the outer cylinder.

The water droplets separated in this way flow on the inner wall of the outer cylinder and the trap housing 8 downwards, while the gas at the lower end of the double cylinder 34 passes into the inner cylinder and into Direction of the main valve 5 and to the outlet channel 23 flows and the separated water through the opening 47 into the Catch cap 46 arrives and the gas contained therein is forced out through ventilation openings 48. Depending on the water level moves the float ball 43 up and down, opening the outlet port of the valve seat 44 and closes so that only water flows out through the outlet opening 45.

Claims (6)

Dr.-lng. Reimar .King · LJipl-lng. Klaus Bergen Wilhelm-Tell-Str. 14 4OOQ Düsseldorf 1 Telephone 39 7O26 Patent Attorneys Feb. 7, 1986 36 538 K TLV Co., Ltd., Hibiya Kokusai Bldg., 8F, 2-3, Uchisaiwai-cho 2-chome Chiyoda-ku, Tokyo, 100 Japan "Steam trap "Claims: 1. Steam trap with an annular space having baffles between a hollow cylindrical partition and a housing, in which the annular space and the interior of the partition are in communication with an inlet, an outlet and an outlet valve, characterized in that on the outside of the partition (34) Inclined ribs (40) and spiral ribs (41) extending gradually from their upper ends to their lower ends and merging stepwise into intermediate walls (42) at the lower ends of the inclined ribs are arranged. 2. Steam trap according to claim 1, characterized in that on the outside of the partition (34) from the upper ends of the inclined ribs (40) upwardly extending longitudinal ribs (39) are arranged. 3. Steam trap according to claim 1 or 2, characterized in that the outer surface of the partition (34) has a roughness like a pear skin. 4. Steam trap according to one or more of claims 1 to 3, characterized in that the lower part of the partition (34) gradually approaches the housing wall and forms an angle of 25 to 50 with the vertical. 5. Steam trap according to one or more of claims 1 to 4, characterized in that the partition (34) consists of two hollow cylinders arranged concentrically at a distance from one another. 6. Steam trap according to claim 5, characterized in that the ends of the inner cylinder are widened in a funnel shape and the outer cylinder has a lower height than the inner cylinder.