DE102013010635B4 - Steam brake / shut-off system - Google Patents

Abstract

Shut-off system for a medium-flow system with an outlet located in the lower part of the system, which outlet is closable by the shut-off system and the shut-off system is a wear-resistant float that floats on the medium while the system is in operation the density of the medium changes so that the float moves down and the outlet for the medium is blocked with solids, in which the float is held in this position until a pressure equalization, characterized in that the wear-resistant float is made of ceramic ,

Description

The invention relates to a vapor barrier / a shut-off system according to the preamble of the claims for the regulation of media with highly abrasive substances.

Float valves have been known for a long time.

A float valve or fill valve is a float controlled valve that basically works as follows:
If the level falls below a certain level, the valve opens and closes again when the desired level is reached.

For this purpose, the float attached to a lever sinks with the liquid level. The shut-off device coupled to the lever is removed from the valve seat, thus opening the valve. Rising liquid level, however, ensures that the shut-off against the valve seat pressed and thus the valve is closed.

Float valves are used to ensure a certain liquid level in containers (eg in a toilet cistern).

The filling valve used in the cistern of a toilet is usually not the simple form of the float valve used, but an integrated version of pilot and main valve, as can be the length of the lever to which the float is attached, significantly shorten. The lever on the float closes the pilot valve (with a much smaller diameter than the main valve). The thus increasing pressure in the pilot valve chamber pushes the positively driven shut-off of the main valve in the closed position.

From the DE 31 17 279 A1 For example, a hydrometer for measuring the density of fluids having coefficients of thermal expansion which vary with density and temperature is known, such an arometer being composed of materials having different coefficients of thermal expansion and being appropriately calibrated.

This density measuring device has two provided as a float hydrometer with the properties mentioned, which are rotatably mounted on a common axis, so that they rotate in opposite directions when changing the density of a liquid in which they are immersed.

The DE 38 15 023 A1 discloses a closure with a relief valve having a closure body attached to an opening of a container such as a fuel tank or radiator of a motor vehicle, a partition wall formed inside the body extending radially from an inner circumferential surface and a first flow port, and a pressure relief valve disposed on the upper side of the partition wall. On the lower side of the partition wall, a support plate provided with a second flow opening is arranged within the main part, wherein an auxiliary valve chamber is formed between it and the partition wall. Within the auxiliary valve chamber are a check valve body having a relative to the liquid in the container greater relative density and a float with such a relative density that the consisting of the check valve body and the float combined body has a lower relative density than the liquid in the container , arranged on the lower side of the first flow opening and movable up and down. When the upper and lower layers of the container are reversed, the shut-off valve body is moved toward the partition by its own weight, so that the first flow-through opening is closed.

From the DE 40 00 037 A1 It is known that for measuring filling levels of media in a container of different densities, which are stacked to form mutable in their height separating layers, a device is provided with a pressure meter having a float, the pressure gauge has a pneumatic supply line. This pneumatic connection is used to measure both the hydrostatic pressure inside the fluid and also to change the altitude of the pressure measuring point or the associated float. The float is designed so that it floats in the region of a separating layer between, for example, water and oil. Thus, the layer thickness above the float can be determined. By lowering the float and the total liquid level can be determined. In addition, it is also possible to determine the layer thickness of a solid layer deposited on the base by settling the float on its surface.

The DE 42 20 642 A1 discloses an apparatus for automatically controlling the outflow of a liquid from a system of at least two immiscible liquids of different densities, of which the liquid to be continuously removed from the system has the higher density. This device comprises a housing, which is connectable to the liquid space and the vapor space of the liquid system, a control device with a float and a cooperable signal generator. In order to allow automatic control of the outflow of liquid to be removed, the housing has in its lower part in the housing bottom or above the housing bottom an outlet opening for the liquid to be removed, the float is a hollow ball with such a weight to volume ratio, that the Hollow ball is floatable in the liquid of higher density and sinkable in the liquid of low density, and the signal transmitter is positioned so that the hollow ball is lowered into the reach or to the top of the signal generator, wherein the opening and closing of the outlet opening through Output of control pulses of the signal generator in response to a predeterminable liquid level to a signal receiver is controllable.

In the DE 10 2006 024 120 A1 describes a float for the production of at least single-walled safety tubes, in particular for use as brake lines in motor vehicles, comprising a shaft with at least one caliber, wherein at least one caliber comprises a hard metal element made of a hard metal or made of a ceramic ceramic element.

• a) die Ventilanordnung wenigstens ein durch die Vorsteuerung rotatorisch und/oder linear betätigtes Ventilglied aus einem keramischem Werkstoff beinhaltet
• b) in dem Ventilglied wenigstens ein mit dem Arbeitsanschluss in Strömungsverbindung bringbarer Verbindungskanal ausgebildet ist, welcher abhängig von der Position des Ventilglieds eine Strömungsverbindung des Arbeitsanschlusses mit einem mit dem Entlüftungsanschluss in Verbindung stehenden ersten Strömungskanal oder mit einem mit dem Speisedruckanschluss in Verbindung stehenden zweiten Strömungskanal herstellt, wobei zumindest ein Abschnitt des ersten Strömungskanals und des zweiten Strömungskanals in wenigstens einem ruhenden Ventilkörper aus keramischem Werkstoff ausgebildet sind,
• c) wenigstens der erste Strömungskanal gegenüber dem zweiten Strömungskanal durch mindestens eine in einem Bereich außerhalb einer direkten Anströmung durch das Druckmittel angeordneten Dichtung abgedichtet ist.

The DE 10 2007 035 775 A1 discloses a pilot operated valve having a valve assembly that switches a fluid flow between at least one working port, a boost port, and a vent port. It is envisaged that

• a) the valve arrangement includes at least one rotationally and / or linearly actuated by the pilot control valve member made of a ceramic material
• b) in the valve member at least one can be brought into fluid communication with the working port connection channel which produces depending on the position of the valve member, a flow connection of the working port with a vent port in communication with the first flow channel or with the feed pressure port in communication with a second flow channel wherein at least a portion of the first flow channel and the second flow channel are formed in at least one stationary valve body of ceramic material,
• c) at least the first flow channel with respect to the second flow channel is sealed by at least one arranged in a region outside a direct flow through the pressure medium seal.

From the DE 10 2008 054 222 A1 is a micro-valve in ceramic multi-layer technology, which has a regulation of z. B. gas flows as a function of the ambient temperature, known. The valve uses a temperature-dependent deformation of a bimetal to regulate the flow.

In addition, the reveals DE 10 2008 054 222 A1 a microvalve assembly having a plurality of such microvalves.

The microvalves according to the invention are used for controlling micro-burners, micro-generators, micro-reformers, microreactors, micro fuel cells, cooling or heating systems, in micro process engineering, in micro energy engineering and in microanalysis.

The DE 39 28 679 A1 discloses a leak detection method for tanks in which the liquid content is determined at intervals and an indication is given when an allowable change is exceeded. For this purpose, pressure differences are determined at intervals between a in the liquid and a connected with a gas cushion over the liquid location, pressure difference changes are determined from time intervals determined pressure differences and time normalized by reference to the time interval between the pressure differences, whereupon determined from the time-normalized pressure difference changes associated time-normal fluid changes be and is checked whether the time-normalized fluid mass changes reach a normalized to the same time interval default value, when exceeded, a display is made.

From the DE 39 40 636 A1 a device for detecting the refrigerant liquid level in a refrigeration or heat pump system using a float body is known. This is characterized by the fact that the float body is variable in volume, and that it is filled with a medium whose vapor pressure is higher than that of the refrigerant.

For a sufficiently accurate detection of the refrigerant liquid level is possible, regardless of the current temperature or the currently prevailing system pressure in the refrigeration or heat pump system.

When relaxing media that are in a system, it is of enormous importance in which state of aggregation the medium is present. This is all the more critical if very high pressure differences between the system and its surroundings are present at high temperatures, the medium is quasi in an overheated state and the state of aggregation even changes during relaxation (eg when the system is opened). Add to this the fact that solids are present in the medium, it is expected to very strong wear of the system. So it is, for example, in water so that when evaporating the water, an approximately 1000-fold volume of vapor (gaseous water) compared to the liquid initial amount of water is formed.

So flows through a line (the system) a suspension, so you can select the parameters and adjust so that it hardly comes to wear. At the moment when the liquid has escaped from the line (system) and continues to follow solid vapor, velocities are immediately generated which cause extensive wear and tear on the walls of the pipe (s), possibly within shortest time can lead to failure of pipeline or plant parts (of the system). It is therefore necessary, at the moment of the transition from liquid to gas (vapor) to automatically close the passage of the system, quasi to brake the steam and prevent it from flowing out.

Out FR 2 601 753 A1 . FR 2 923 399 A1 and FR 2 899 947 A1 are automatically functioning, simple shut-off systems for a medium permeable with a medium system known per se.

For example, FR 2 601 753 A1 discloses a shut-off system with an outlet located in the lower part of the system, which outlet can be closed by the shut-off system and the shut-off system is a wear-resistant buoyant that can be floated on the medium while the system is operating the density of the medium changes in such a way that the float moves downwards and blocks the outlet for the medium with solids, in which the float is held in this position until a pressure equalization takes place.

The disadvantage of this technical solution according to FR 2 601 753 A1 and the solutions according to FR 2 923 399 A1 and FR 2 899 947 A1 is that in abrasive media tremendous wear on the shut-off system, in particular on the float by abrasion occurs, which may possibly lead to failure of the shut-off system within a very short time.

The invention is therefore based on the object to provide a shut-off system for a medium permeable with a medium system, which avoids the high wear by abrasion on the float.

This object is achieved by a shut-off system according to claim 1. Advantageous embodiments are specified in the dependent subordinate claims.

The essence of the invention is to provide a ceramic shut-off system in which a ceramic float floats on a liquid (a suspension / medium) (which contains solids) until the density of the medium (liquid) is maintained Medium) such that the float moves down and obstructs the passage for the medium. Just at the moment when the float becomes heavier than the displaced medium (now in the form of a gas-solid mixture, possibly also liquid therewith), the float completes the passage. Since further pressure (gas pressure) is applied, the float is held in the sealing position until a pressure equalization is created again.

The pressure balance can z. B. by "back pressures" of liquid. Since the media are very abrasive substances, it is not possible to use simple metallic floating bodies as they wear out and leak relatively quickly.

In the case of the provided ceramic body, which is harder in hardness than the solids contained in the medium, the medium can not wear the sealing elements, the closure of the passage is maintained.

It is therefore essential to the invention that the floating body must be made wear-resistant, for example made of ceramic.

Claims (4)

Shut-off system for a medium-flow system with an outlet located in the lower part of the system, which outlet is closable by the shut-off system and the shut-off system is a wear-resistant float that floats on the medium while the system is in operation the density of the medium changes so that the float moves down and the outlet for the medium is blocked with solids, in which the float is held in this position until a pressure equalization, characterized in that the wear-resistant float is made of ceramic , Shut-off system for a system through which a medium can flow with solids according to claim 1, characterized in that, in the operating state of the shut-off system, the outlet of the system can be automatically closed precisely at the moment of the transition of the medium from the liquid to the vapor or gaseous state. Shut-off system for a system through which a medium can flow with solids according to claim 1, characterized in that in the operating state of the shut-off system by pressure equalization, the output of the system is automatically openable. Use of a shut-off system according to any one of the preceding claims 1 to 3 for the regulation of a solids-containing medium stream.