WO1998042433A1

WO1998042433A1 - Method and device for discharging a liquid-dissolved or finely distributed medium

Info

Publication number: WO1998042433A1
Application number: PCT/EP1998/000409
Authority: WO
Inventors: Wilfried Wiegers
Original assignee: Wilfried Wiegers
Priority date: 1997-03-21
Filing date: 1998-01-26
Publication date: 1998-10-01
Also published as: DE59804892D1; EP0968049B1; AU6616198A; DE19711855A1; EP0968049A1; DE19711855C2; ATE220947T1; DE19711855C5

Abstract

The invention relates to a method for discharging a liquid-dissolved or finely distributed medium enabling said substance to be used in a remote place from the point of discharge. A limited amount of liquid is arranged in a tubular housing with one open end. At the other end of the housing, a highly pressurized gaseous blowing agent is applied to the liquid for a short period in order to produce a flying jet of limited length.

Description

Method and device for discharging a medium dissolved or finely distributed in a liquid

The invention relates to a method for discharging a medium, which is dissolved or finely distributed in a liquid, to a location located away from the discharge location according to the preamble of patent claim 1.

From EP 0 402 425 a device for dispersing liquid or powder using gas under pressure has become known. The liquid or powder is taken up in a first reservoir and a second reservoir is filled with gas under pressure. By discharging the gas reservoir onto the liquid container, the liquid or powder is expelled explosively and the liquid or powder is finely distributed outside the device. The "cloud" of tiny liquid particles, especially water or powder, can be used effectively for fire fighting.

There is often a need to discharge a medium which is dissolved or finely distributed in liquid to a remote location, for example water mixed with so-called irritant gas. which the police use in operations in the case of demonstrations or the like. Similar applications are conceivable for pest control. The known device is not suitable for such operations, because there is a risk that the operator may be hit by parts of the discharged medium driven back by the wind.

The invention is therefore based on the object of specifying an effective method for discharging a medium dissolved or finely distributed in a liquid, in which an operator cannot be hit by parts of the discharged medium deflected by wind.

This object is achieved by the features of patent claim 1.

In the method according to the invention, the liquid receiving the substance or the medium is held in a tubular housing which is open at one end. The open end is preferably provided with a jet shaping device. A gas under pressure is suddenly applied to the other end of the housing over a period of time. It must be ensured that the liquid is essentially discharged as a column and does not immediately disperse into fine droplets when it hits air. A relatively high pressure is therefore required, but it must not happen that the gaseous propellant makes its way through the liquid column and pulls the fluid behind it according to the jet pump principle and swirls it strongly. By means of the method according to the invention, a beam of limited length emerges from the tubular housing, which detaches from the housing and strikes the application site after a certain flight time. The distance covered distance is 20 to 25 m if a liquid amount of about 1 1 is used. Pressure and volume of the liquid as well as the gaseous propellant must be coordinated accordingly in order to achieve the desired result. The "flying" jet begins to fan out after a certain distance of its trajectory, so that a limited area is covered with liquid particles at the application site. This is also desirable for most applications.

In a device according to the invention, two cylindrical reservoirs are arranged coaxially to one another, a liquid, e.g. Water is contained in which a medium, for example a certain active ingredient, is dissolved or finely divided. A gas is stored under pressure in the outer cylinder, which forms an annular space with the inside. However, both reservoirs can be permanently connected to a supply source so that they can be refilled from the first reservoir after a predetermined amount has been dispensed. At the exit of the first reservoir there is also a jet shaping device which ensures that the liquid emerges as a jet, but in a more or less fine distribution, such as e.g. is the case with shower heads.

The device according to the invention also has a valve piston which is controlled by a pneumatic control device in order to bring the valve piston into one of two possible positions. In the closed position, the valve piston rests on the associated end face of the inner cylinder tube and therefore closes the passage between the annular space between the inner and outer tubes. In the open position, however, this passage is released, which therefore forms an annular gap, through the gas under pressure on the liquid column in the inner reservoir to squeeze out the liquid. The valve piston is normally held in the closed position by a differential pressure between a first active surface of the valve piston, which faces the annular space, and an opposite active surface, which is exposed to the pressure in the second reservoir. However, if the second active surface is vented, the now changed pressure drop at the valve piston causes it to open, so that the described discharge can take place. Since the ventilation is only temporary, a pressure builds up again on the second active surface, and the pressure on the entire end face of the piston, which is facing the two cylinder tubes, decreases relatively quickly, so that the valve piston then moves back into the closed position becomes.

The pulsed discharge of an intended amount of liquid, e.g. 1 is 1, takes place in a very short time. As already described, however, reloading can take place, so that the described process can be repeated as long as the liquid and the pressurized gas source are not exhausted.

It could be considered to consider the volume of the propellant gas, e.g. Air to limit what can be accommodated in the second reservoir at a certain pressure. However, it has proven to be advantageous if it is ensured that the normally available pressure source remains connected to the second reservoir during the discharge of the liquid in order to increase the propulsion volume. This creates a stable beam with the desired distribution pattern.

According to one embodiment of the invention it is provided that the valve piston has a first cylindrical sealing section has, the end face of which cooperates with the first reservoir and which is slidably and sealingly movable in a first bore section, a second cylindrical sealing section with a smaller diameter which is slidably and sealingly movable in a second bore section and a third cylindrical sealing section which fits into a Bore immerses when the valve piston is in the open position, but is arranged in the closed position in a space which is separated from the second sealing section from a second space which is formed between the valve piston and the housing for the valve piston, this space via a radial bore is constantly associated with atmosphere. A vent valve is associated with the first space and a pressure source for gas is connected to the bore, the bore being connected to the second reservoir via a check valve. With such a control valve arrangement, the operation described above can be achieved in a simple constructive manner.

Various constructive solutions are conceivable for the jet former. According to one embodiment of the invention, a particularly advantageous feature is that a hole nozzle has a central hole and a ring of individual holes arranged concentrically to the hole at a radial distance from the central hole.

The invention is explained in more detail below with reference to drawings.

Fig. 1 shows a section through a schematically illustrated device for performing the method according to the invention. FIG. 2 shows a front view of a jet nozzle for the device according to FIG. 1.

Fig. 3 shows a section through the nozzle of Fig. 2 along the line 3-3.

1 shows a device 10 with a housing, which is composed of a cylindrical outer tube 12, a cylindrical inner tube 14, which is at a radial distance from the outer tube 12, and a block 16. The outer tube 12 is placed on a shoulder of the block 16, for example screwed. An annular space 18 is formed between the inner and outer cylinders. A valve piston 20 is arranged in a space formed between the cylinders 12, 14 and the block 16. The valve piston 20 has a first sealing section 22, which cooperates with a sealing ring 24 in a sealing manner with the inner wall of the outer cylinder 12. The left front surface of the sealing section 22 has a recess in which a sealing disk 26a is received, which cooperates with the facing end of the inner tube 14. In Fig. 1, the closed position of the valve piston 20 is shown. A second cylindrical sealing section 26 of the valve piston 20, which is provided with a sealing ring 28, cooperates with a bore section 30 of smaller diameter of the block 16. A third sealing section 32 of even smaller diameter, which does not have a sealing ring, can be inserted in a central bore 34 in the block 16. In the position of the valve piston 20 shown in FIG. 1, the sealing section 32 is located in a bore section 36 whose diameter is larger than that of the bore section 30. A section of the piston 20 lying between the sealing sections 22, 26 has a somewhat smaller diameter, so that a space 38 is formed, which is constantly connected to the atmosphere via a radial bore 40 in the outer tube 12. The inner tube 14 is connected via a filling device (not shown) to a reservoir 42 via a valve 41 for liquid, in which a medium is dissolved or finely distributed. The medium can be a chemical agent, for example. The central bore 34 is connected to a compressed gas source 48, for example compressed air, via a filling device (not shown) and a throttle arrangement 46. The space 48 formed by the bore section 36 is connected to a vent valve 50. A connecting line 52 connects the bore section 34 to the annular space 18 via a check valve 52.

The left end of the tube assembly 12, 14, which is not shown, cooperates with a jet nozzle 54, which is shown in FIGS. 2 and 3. It is attached to the end of the arrangement in such a way that only the medium can escape from the interior of the cylinder tube 14 via the nozzle arrangement 54. This has a central hole 56 and a ring of holes 58 which is arranged concentrically with the central hole 56. At the end facing the cylinder tube 14, the nozzle arrangement 54 has a conical recess 60 which tapers towards the central hole 56.

In the state of the device according to FIG. 1, as mentioned, there is liquid in the inner cylinder 14 with a medium which has been filled in by a source 42. Compressed gas with a pressure of, for example, 25 bar is located in the annular space 18. This pressure acts on the annular surface of the sealing section 22 of the piston 20 between the inner cylinder 14 and the outer cylinder 12. This pressure also acts on the opposite active surface 62 of the piston 20. Since this and the active surface of the sealing section 32 is larger than the mentioned annular active surface, the Piston 20 held in the closed position shown. By opening the Ventilation valve 50, which can be actuated for example by a lever or a trigger, the space 48 is vented to the atmosphere. As a result, the pressure on the annular active surface 64 is able to bring the piston 20 to the right into the open position. As soon as the seal 28 has passed the edge 66 between the bore sections 30, 36, the space 48 is also in connection with the space 38 and is thus connected to the atmosphere via the bore 40. The sealing section 32 is immersed in the bore 34, so that pressure only acts on the piston 20 via the active surface of the sealing section 32.

By displacing the piston 20, an annular gap is formed toward the inside of the inner tube 14, through which the compressed gas can drive out the liquid via the nozzle arrangement 54. The nozzle arrangement forms a more or less finely distributed, but relatively wide jet. Because of the constant connection between the bore 34 and the annular space 18, a certain amount of compressed gas still flows in to effect the expulsion of the liquid. However, if the pressure on the entire end face of the sealing section 22 decreases due to the expulsion process, the pressure on the active surface of the sealing section 32 is sufficient to move the piston back into the closed position. This pressure increases the moment the seal 28 re-enters the bore section 30. As soon as the two reservoirs for liquid and compressed gas are refilled, which is the case within a short time, another jet can be emitted.

Claims

Expectations

1. A method of discharging a substance dissolved or finely divided into a liquid for use of the substance at a location away from the discharge location, in which a limited amount of liquid is placed in a tubular housing open at one end and gaseous propellant under high pressure is briefly applied to the liquid at the other end of the housing so that a flying jet of limited length is generated.

2. Device for performing the method according to claim 1, with a first cylindrical reservoir (14) for the liquid with the medium, a second cylindrical reservoir (12) for gas under pressure, which concentrically surrounds the first reservoir (14) at a radial distance , a valve piston (20) movable between two positions, which in a closed position seals against the end of the first cylindrical reservoir (14) and seals the annular space (18) between the cylindrical reservoirs (14, 12) and in its open position an annular gap between releases the first and second reservoirs (14, 12), a pneumatic control device for the valve piston (20) such that the valve piston (20) is held in the closed position by the pressure of the second reservoir (12) acting on a first effective surface (62) is opposed to the pressure of the second reservoir acting on the annular effective surface (64) of the piston (20) corresponding to the annular space (18) s (12) and the piston (20) is moved into the open position when the space (48) facing the first active surface (62) is vented, and a jet shaping device (54) at the outlet of the first reservoir (14).

3. Apparatus according to claim 2, characterized in that a compressed gas source (48) via a check valve (52) is in constant communication with the second reservoir (12).

4. Apparatus according to claim 2 or 3, characterized in that the valve piston (20) has a first cylindrical sealing section (22), the end face of which cooperates with the first reservoir (14) and which is slidably and sealingly movable in a first bore section, one second cylindrical sealing section (26) with a smaller diameter, which is slidably and sealingly movable in a second bore section (30) and a third cylindrical pin-like sealing section (32), which dips into a bore (34) when the valve piston (20) is in contact is in the open position, but in the closed position is arranged in a space (48) which is separated from the second sealing section (26) from a second space (38) which is formed between the valve piston (20) and a housing, the latter Space (38) is constantly connected to the atmosphere via a radial bore (40), with a vent valve (50) which is connected to the first space (48) v is connected, a pressure source (48) for gas, which is connected to the bore (34) and a connecting line between the bore (34) and the second reservoir (12) via a check valve (52).

5. Device according to one of claims 2 to 4, characterized in that a perforated nozzle (54) is arranged at the front end of the first reservoir (14).

6. The device according to claim 5, characterized in that the perforated nozzle (54) has a central hole (56) and one Has concentric ring of holes (58) at a radial distance from the central hole (56).

7. Device according to one of claims 2 to 6, characterized in that in the end face of the valve piston (20) a disc (26 a) made of sealing material is used.