The invention relates to a metering apparatus for introducing a powdery medium into a fluid. The invention also relates to a mixing system with a metering apparatus of this type for mixing a drilling fluid, as well as a method for introducing a powdery medium into a fluid.
It is known to use a drilling fluid for supporting the drill feed when constructing ground drill holes and in particular horizontal drill holes. The drilling fluid is used to soften the ground in advance of the drill head of the drilling apparatus in order to improve the cutting performance of the drill head. The drilling fluid can also be used to lubricate the drill head and the drill rods, which are rotatably driven in the drill hole, so as to reduce friction with the ground. In addition, the drilling fluid can be used to flush out the soil removed by the drill head through the annular gap between the drill rod and the wall of the drill hole or through an annular gap of dual drill rods.
The drilling fluid is typically a mixture of water and bentonite, and sometimes several additives. Bentonite is a mixture of different clay materials, with the largest component being montmorillonite (generally with a content of 60% to 80%). Additional accompanying materials may be quartz, mica, feldspar, pyrite and sometimes also calcite. Due to the montmorillonite content, bentonite has strong water absorption and swelling capability.
Water into which bentonite is stirred can have thixotropic characteristics, so that it behaves like a fluid when in motion, but like a solid structure when at rest. Because of this behavior, a drilling fluid composed of water and bentonite can also be used for supporting the wall of the drill hole, thereby preventing a collapse.
The introduction of bentonite into water poses a particular challenge, because the bentonite has the tendency to lump together in contact with water. In the state-of-the-art, the drilling fluid is typically stirred in large storage vessels with dynamic mixing apparatuses and thereafter transported in batches to the construction site where the drilling fluid is to be used. However, such batch-wise mixing is quite cumbersome. In addition, after the drill hole has been completed, the unused portion of the last batch must be disposed of, which is complex and expensive.
Another conventional method and a corresponding mixing apparatus are known, which eliminate this disadvantage of batch-mixing of a drilling fluid. With this approach, the bentonite is introduced directly in the water in the region of a high-pressure pump, which is provided for transporting the drilling fluid through the drill rod to the drill head of a horizontal drilling apparatus, in order to take advantage of the turbulences produced in the water by the high-pressure pump for mixing the bentonite with the water. A swelling section can be arranged downstream of the high-pressure pump, where the bentonite-water-mixture is given time to swell before it is transported through the drill rod to the drill head.
Such method for continuous mixing of a drilling fluid and a corresponding continuous flow mixing system are disclosed in DE 199 18 775 B4. However, this document does not disclose the manner in which the powdery bentonite is actually introduced into the water.
Starting from the aforedescribed state-of-the-art, it was an object of the invention to provide an improved metering apparatus for introducing a powdery medium into a fluid, with which the problem associated with the powdery medium lumping together upon contact with the fluid, known from the state-of-the-art, can at least be reduced. According to the invention, a corresponding method and a mixing system for mixing a drilling fluid will also be described.
This object is attained with the features recited in the independent claims. Advantageous embodiments are recited in the respective dependent claims and disclosed in the following description of the invention.
The core of the invention is directed to improving mixing of the powdery medium with the fluid by scattering the powdery medium onto the surface of the fluid in a metered form. Scattering the powdery medium onto the surface of the fluid results in a fine distribution of the individual particles of the powdery medium already at the time of the first contact with the fluid, thereby effectively preventing lumping.
In the context of the invention, “scattering” refers to dispensing the particles of the powdery medium from the metering device and/or applying the powdery medium on the fluid surface as finely distributed as possible. Scattering according to the invention can occur through gravity; however, pressure-aided dispensing, for example in conjunction with compressed air or other auxiliary means for accelerating a particle may also be included in the term “scattering” according to the invention. However, a combination of gravity-fed and pressure-aided scattering is also feasible.
A particularly fine distribution of the powdery medium on the fluid surface can be achieved with a continuous flow of the fluid through the guide device, as is the case, for example, in a continuous flow mixing apparatus for producing a drilling fluid.
According to the invention, the distribution of the powdery medium in the fluid can advantageously be further improved by designing the guide device below the metering unit so that a fluid film is created with a width that is a multiple of its depth. With this configuration of the metering apparatus according to the invention, the powdery medium can already be so finely distributed on or in the fluid that complex mixing with static or dynamic mixing units may no longer be necessary.
Advantageously, the metering apparatus according to the invention may be provided with a pump; this particularly applies when a metering apparatus according to the invention is integrated in a continuous flow mixing system for a drilling fluid, wherein a pump is typically already installed for transporting the mixed drilling fluid through a drill pipe to a drill head.
According to the invention, the metering device may form a metering gap, with which the powdery medium can be distributed over a large-area on the fluid surface. With the metering apparatus according to the invention, the metering gap may advantageously have a length which corresponds substantially to the width of the guide device. The powdery medium can thus be scattered according to the invention over the entire surface of the fluid film.
In a preferred embodiment of the metering apparatus according to the invention, the metering gap may be formed by a (first) metering roller and a corresponding counter element. By providing a metering roller, the powdery medium can be continuously dispensed even if the metering gap is very small; the metering roller(s) may dissolve lumps of the powdery medium, thereby preventing clogging of the metering gap. With the rotating motion of the metering roller, a fine film of the powdery medium can be formed and pushed through the metering gap. This may cause the film of the powdery medium to adhere to the surface of the metering roller. The metering roller may have a suitably formed (e.g. roughened) surface which aids a continuous formation of a film of the powdery medium on the surface of the metering roller.
To detach a film of the powdery medium adhering to the surface of the metering roller, so that this film may be scattered according to the invention on the fluid surface, the film may be detached from the surface of the metering roller with a stripping element.
In another preferred embodiment of the metering apparatus according to the invention, the counter element may also be constructed as a (second) metering roller. In this way, a particularly fine film of a powdery medium can be obtained on the surface of one or both metering rollers. This applies particularly to the preferred embodiment of the metering apparatus according to the invention, wherein the two metering rollers are driven for rotation in the same direction, forming opposing tangential velocity components in the metering gap.
In another embodiment, the metering gap may be formed by two plates facing each other, preferably with a conical orientation. The two conically oriented opposing plates may form an intermediate reservoir in form of a funnel and thus enable very finely metered dispensing of the powdery medium, which can then be scattered on the fluid surface.
Clogging of the metering gap formed by the plates by lumps that may be present in the powdery medium can be prevented by moving the plates cyclically with a drive in opposing directions. The finely metered powdery medium can then be continuously dispensed. The direction of the cyclical relative movement of the two plates may preferably be parallel to the gap, because the gap width is then not changed in spite of the relative movement of the flaps. However, it will be understood that other movement directions are also feasible.
According to another preferred embodiment of the metering apparatus according to the invention, a metering brush may be provided to further separate and, if desired, also accelerate the particles of the powdery medium. In particular, the metering brush may be constructed as a roller, with a rotation of the roller-shaped metering brush enabling a continuous motion. For example, the metering brush may be provided to brush off a film of the powdery medium formed on a metering roller, whereby the particles are scattered in finely metered form on the liquid surface.
In a preferred embodiment of the metering apparatus according to the invention, the powdery medium may be supplied to the metering device with a feed screw. It will be understood that other feed devices may also be used, for example a funnel, through which the powdery medium can be gravity-fed to the metering device.
The metering apparatus according to the invention is particularly suited for introducing bentonite into an aqueous fluid and in particular into (pure) water.
The method according to the invention for introducing a powdery medium into a fluid is characterized in that the powdery medium is scattered on the fluid surface in metered form.
A mixing system according to the invention for mixing a drilling fluid includes a metering apparatus according to the invention as well as a bentonite feed operatively connected with the metering device of the metering apparatus, a water feed operatively connected with the guide device of the metering apparatus according to the invention, as well as a pump.
Preferably, the pump of the mixing system according to the invention may be a high-pressure pump, enabling the construction of a continuous flow mixing system, because a high pressure pump generates a pressure that is sufficient for transporting the drilling fluid through a hollow drill pipe.
The invention will now be described in more detail with reference to exemplary embodiments illustrated in the drawings.
The drawings show in:
a in a side view, the water inlet of
b in a side view, the water inlet of
The housing 1 which is accessible, as illustrated in
The transport roller 5, the metering roller 6 and the brush roller 7 are connected via drive shafts with electric drives that are flanged to the rear side of the housing 1 (see
The metering apparatus illustrated in
For forming the water film, the water (or another fluid to be mixed with the powdery medium) is discharged through the water inlet 3 and a slit-shaped outlet opening 25 formed in the water inlet 3 (see
For forming the water film, the water is fed via an inlet tube 236 having an (unillustrated) slit-shaped opening and a width that corresponds substantially to the width of the housing 201 of the metering apparatus. The inlet tube 236 may, like the water inlet 3 of
To support a continuous discharge of the bentonite powder through the gap formed by the metering plates 235, the two metering plates 235 are moved cyclically relative to one another (with opposite phases), as shown in
The structural and functional details of the aforedescribed exemplary embodiments cannot only be applied in the respective actually disclosed combination, but can be applied in any combination also with other combination filters according to the invention.
Number | Date | Country | Kind |
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10 2009 023 546.9 | May 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/003224 | 5/27/2010 | WO | 00 | 2/27/2012 |