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Claims  |
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I claim:
1. In a process of replacing an enclosed old pipe with a new pipe, said
process including advancing a cutter head along said old pipe and
operating said cutter head to cut away and thereby remove said old pipe,
and supplying said new pipe behind said advancing cutter head, the
improvement comprising:
controlling the direction of advancement of said cutter head to accurately
follow said old pipe by guiding said advancement directly along an inner
wall surface of said old pipe, said guiding comprising mounting a guide
mechanism on a leading end of said cutter head, inserting said guide
mechanism into said old pipe forwardly of said cutter head and urging said
guide mechanism outwardly against said inner wall surface of said old
pipe, such that during advancement of said cutter head said guide
mechanism follows said inner wall surface and constrains said cutter head
to precisely follow said guide mechanism along said old pipe.
2. The improvement claimed in claim 1, further comprising adjusting the
pressure of outward urging of said guide mechanism.
3. The improvement claimed in claim 1, wherein said guide mechanism
includes at least two supporting elements, and said urging comprises
pressing said supporting elements radially outwardly to maintain said
guide mechanism centered with respect to said inner wall surface.
4. The improvement claimed in claim 1, wherein said advancing comprises
pulling said cutter head in said direction axially of said old pipe.
5. The improvement claimed in claimed 1, wherein said advancing comprises
pushing said cutter head in said direction by said new pipe.
6. The improvement claimed in claim 1, wherein said old pipe comprises a
buried sewer pipe.
7. The improvement claimed in claim 6, wherein said cutter head and said
new pipe have a diameter greater than that of said old pipe, and said
cutter head cuts away material surrounding and burying said old pipe.
8. In an apparatus for replacing an enclosed old pipe with a new pipe, said
apparatus including a cutter head to be advanced along the old pipe while
being operated to thereby cut away and remove the old pipe, with a new
pipe being supplied behind the thus advancing said cutter head, the
improvement comprising:
a guide mechanism mounted on a leading end of said cutter head such that
said cutter head is rotatable relative to said guide mechanism, said guide
mechanism extending from said cutter head to fit against an inner wall
surface of the old pipe and thereby to be centered relative thereto, and
thus to guide the direction of advancement of said cutter head to
accurately follow the old pipe.
9. The improvement claimed in claim 8, further comprising a motor for
rotating said cutter head.
10. The improvement claimed in claim 9, wherein said motor is connected
indirectly to said cutter head at a position to be outwardly of the old
pipe.
11. In an apparatus for replacing an enclosed old pipe with a new pipe,
said apparatus including a cutter head to be advanced along the old pipe
while being operated to thereby cut away and remove the old pipe, with a
new pipe being supplied behind the thus advancing said cutter head, the
improvement comprising:
a guide mechanism mounted on said cutter head and extending therefrom to
fit against an inner wall surface of the old pipe and thereby to be
centered relative thereto, and thus to guide the direction of advancement
of said cutter head to accurately follow the old pipe, said guide
mechanism comprising a bearing body connected to said cutter head to
enable relative rotation therebetween, and at least two supporting
elements mounted on said bearing body for adjustable movement radially
thereof to be pressed against the inner wall surface of the old pipe at
adjustable pressure, said supporting elements together defining a
substantially cylindrical outer shape.
12. The improvement claimed in claim 11, further comprising piston-cylinder
units mounting said supporting elements for radially adjustable movement
relative to said bearing body, and each said supporting element has an
outer partially cylindrical surface to be pressed against the inner wall
surface of the old pipe.
13. In an apparatus for replacing an enclosed old pipe with a new pipe,
said apparatus including a cutter head to be advanced along the old pipe
while being operated to thereby cut away and remove the old pipe, with a
new pipe being supplied behind the thus advancing said cutter head, the
improvement comprising:
a guide mechanism mounted on said cutter head and extending therefrom to
fit against an inner wall surface of the old pipe and thereby to be
centered relative thereto, and thus to guide the direction of advancement
of said cutter head to accurately follow the old pipe, said guide
mechanism being adjustable relative to said cutter head in a direction
radially thereof.
14. In an apparatus for replacing an enclosed old pipe with a new pipe,
said apparatus including a cutter head to be advanced along the old pipe
while being operated to thereby cut away and remove the old pipe, with a
new pipe being supplied behind the thus advancing said cutter head, the
improvement comprising:
a guide mechanism mounted on said cutter head and extending therefrom to
fit against an inner wall surface of the old pipe and thereby to be
centered relative thereto, and thus to guide the direction of advancement
of said cutter head to accurately follow the old pipe, said cutter head
having an axis of rotation positioned eccentrically of a longitudinal axis
of said guide mechanism, and said cutter head having an outer diameter
greater than a maximum outer diameter of said guide mechanism.
15. In an apparatus for replacing an enclosed old pipe with a new pipe,
said apparatus including a cutter head to an advanced along the old pipe
while being operated to thereby cut away and remove the old pipe, with a
new pipe being supplied behind the thus advancing said cutter head, the
improvement comprising:
a guide mechanism mounted on said cutter head and extending therefrom to
fit against an inner wall surface of the old pipe and thereby to be
centered relative thereto, and thus to guide the direction of advancement
of said cutter head to accurately follow the old pipe, said guide
mechanism having circumferentially distributed cutting elements cooperable
with said cutter head to comminute reinforcements in the old pipe,
16. In an apparatus for replacing an enclosed old pipe with a new pipe,
said apparatus including a cutter head to be advanced along the old pipe
while being operated to thereby cut away and remove the old pipe, with a
new pipe being supplied behind the thus advancing said cutting head, the
improvement comprising:
a guide mechanism mounted on said cutter head and extending therefrom to
fit against an inner wall surface of the old pipe and thereby to be
centered relative thereto, and thus to guide the direction of advancement
of said cutter head to accurately follow the old pipe; and
a device to prevent rotation of said guide mechanism.
17. The improvement claimed in claim 16, wherein said device comprises a
rod having a first end connected to said guide mechanism and a second end
leading through the old pipe to be held at a manhole at an end thereof.
18. In an apparatus for replacing an enclosed old pipe with a new pipe,
said apparatus including a cutter head to be advanced along the old pipe
while being operated to thereby cut away and remove the old pipe, with a
new pipe being supplied behind the thus advancing said cutter head, the
improvement comprising:
a guide mechanism mounted on said cutter head and extending therefrom to
fit against an inner wall surface of the old pipe and thereby to be
centered relative thereto, and thus to guide the direction of advancement
of said cutter head to accurately follow the old pipe, forward and
rearwards ends of said cutter head being sealed to define a sealed space
maintained at an overpressure.
19. In a process of replacing an enclosed old pipe with a new pipe, said
process including advancing a cutter head along said old pipe and
operating said cutter head to cut away and thereby remove said old pipe,
and supplying said new pipe behind said advancing cutter head, the
improvement comprising:
prior to cutting away of said old pipe by said cutter head, reaming out the
interior of said old pipe by a cutter separate from said cutter head, and
thereby providing said interior of said old pipe to be of approximately
constant diameter; and
controlling the direction of advancement of said cutter head to accurately
follow said old pipe by guiding said advancement directly along an inner
wall surface of said old pipe.
20. The improvement claimed in claim 19, wherein a guide mechanism is
mounted on a leading end of said cutter head, and said guiding comprises
inserting said guide mechanism into said old pipe forwardly of said cutter
head and urging said guide mechanism outwardly against said inner wall
surface of said old pipe, such that during advancement of said cutter head
said guide mechanism follows said inner wall surface and constrains said
cutter head to precisely follow said guide mechanism along said old pipe.
21. The improvement claimed in claim 20, further comprising adjusting the
pressure of outward urging of said guide mechanism.
22. The improvement claimed in claim 20, wherein said guide mechanism
includes at least two supporting elements, and said urging comprises
pressing said supporting elements radially outwardly to maintain said
guide mechanism centered with respect to said inner wall surface.
23. The improvement claimed in claim 19, wherein said advancing comprises
pulling said cutter head in said direction axially of said old pipe.
24. The improvement claim in claim 19, wherein said advancing comprises
pushing said cutter head in said direction by said new pipe.
25. The improvement claimed in claim 19, wherein said old pipe comprises a
buried sewer pipe.
26. The improvement claimed in claim 25, wherein said cutter head and said
new pipe have a diameter greater than that of said old pipe, and said
cutter head cuts away material surrounding and burying said old pipe.
27. In an apparatus for replacing an enclosed old pipe with a new pipe,
said apparatus including a cutter head to be advanced along the old pipe
while being operated to thereby cut away and remove the old pipe, with a
new pipe being supplied behind the thus advancing said cutter head, the
improvement comprising:
a guide mechanism mounted on said cutter head and extending therefrom to
fit against an inner wall surface of the old pipe and thereby to be
centered relative thereto, and thus to guide the direction of advancement
of said cutter head to accurately follow the old pipe; and
a motor for rotating said cutter head and connected directly thereto at a
position to advance therewith along the old pipe. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
Whole sections of current sewer systems in Europe are in need of
replacement due to corrosion, sinking or other damages of leaking sewer
pipes and as a consequence of undersizing, because in many cases original
planning of housing development and the volume of sewerage per inhabitant
were insufficient for the later development.
To replace such sewer pipe, there exists a press pipe tunnelling process,
in which pits or manholes are excavated at intervals of about 60 or more
meters along the sewer pipe at existing inspection chambers or inspection
chambers to be built (DE-OS No. 36 20 026). Starting from a manhole, a
cutter head is advanced along the pipe to be replaced. A pivot bearing of
the cutter head is mounted on the front end of a pipe segment of the new
sewer pipe. The new pipe is pressed forward by means of the cylinder units
with the cutter head starting from the manhole in the direction of the
pipe to be replaced. Other product pipes are attached in succession on the
rear end of the new pipe segment. This procedure has the advantage that
the sewer pipe to be replaced does not have to be exposed over its entire
length, so that the obstruction to traffic is less grave.
Of course, this known device has difficulties with the working of
reinforced concrete pipes and the guidance of the cutter head. It is often
desired to run the new pipe on the same level as the old pipe. If the new
pipe has a larger diameter, its axis is, therefore, higher than that of
the old pipe. In addition, sewer pipes are frequently cemented into the
ground, whereby the thickness of the concrete usually fluctuates over the
circumference. At the top, for example, thickness is the thinnest.
Both of the aforementioned circumstances cause the prior art device to
shift slightly to the side or to the top. Thereafter, a radial
misalignment of the cutter head hardly can be corrected.
SUMMARY OF THE INVENTION
The object of the present invention is to provide an improved process and
device of the aforementioned kind, whereby the above problems are avoided.
With the process of the invention it is achieved in an advantageous manner
that the advanced cutter head, attacking at a face of the old buried or
enclosed pipe to be worked or removed is always centered relative to such
old pipe, even if unilateral forces act on this cutter head owing to the
different thicknesses of the wall of the pipe.
The cutter head is pivoted in an advantageous manner by means of a guide
mechanism which is mounted on the face of the cutter head and is pressed
with adjustable pressure against the inner wall of the old pipe to be
worked and is guided slidingly therein.
The cutter head is either pulled or preferably pushed directly behind an
inserted replacement pipe.
So that the guide mechanism does not suddenly stand still or jam in the
pipe to be worked owing to diameter constrictions, this pipe is calibrated
throughout preferably with a separate cutter prior to replacement.
In the case of the device to carry out the process according to the
invention, the cutter head is off-centered in an advantageous manner
relative to the longitudinal axis of the pipe to be worked, whereby the
cutter head provided with the larger outer diameter makes it possible to
lay the new pipe with respect to the old pipe either below the level or at
the same level. This has the advantage that when only subsections of the
sewer system are provided with new larger pipes, there is no shifting to
the bottom and thus neither water ledges nor eddies can form.
Furthermore, the device according to the invention is provided with cutting
elements which are distributed over the circumference of the guide
mechanism and attach directly to the cutting edges of the cutter head and
interact with the cutter head. When the cutter head then is rotated, any
reinforcing steel is sheared off and comminuted.
BRIEF DESCRIPTION OF THE DRAWINGS
In the following, embodiments and other advantages of the invention are
explained in detail with reference to the accompanying drawings, wherein:
FIGS. 1 and 2 are longitudinal views of two adjacent parts of the device of
the invention;
FIGS. 3 and 4 are longitudinal views of two parts of a second embodiment;
FIG. 5 is a simplified longitudinal view of a third embodiment;
FIG. 6 is an enlarged view of one part of the embodiment according to FIG.
5;
FIG. 7 is a longitudinal view of a fourth embodiment;
FIG. 8 is a front view of a cutting ring; and
FIG. 9 is a front view of a cutter head.
DETAILED DESCRIPTION OF THE INVENTION
FIGS. 1 and 2 depict diagrammatically a device 1 to replace old or existing
sewer pipes 2. The device 1 comprises a rotary drive 3, a stroke drive 4,
a pull rod 5, a cutter head 6 and a guide mechanism 7. The device 1 is
intended for installing a new sewer pipe 8 in place of the pipe 2 and is
installed between two manholes 10, 11 in the sewer system.
The manholes 10, 11 are formed by vertical concrete pipes 12, which in the
ready-for-use state are filled at the bottom with concrete up to about the
bottom edge of the sewer pipe 2. A layer of mortar is applied on this
bottom, and in such layer of mortar is a channel that forms a continuation
of the bottom half of the inner surface of the pipe 2. The device 1 and
all of the necessary arangements thereof are then erected altogether.
Starting from one of the two manholes 10, 11, the pull rod 5 is assembled
from segments 16. The face ends of the segments 16 are connected
tension-proof and twist proof in both directions, as indicated by
crossbolts 17 in FIG. 1. The segments 16 are depicted as
circular-cylindrical pipes, one end of each of which includes a
cylindrical extension 18 of smaller diameter in order to receive the
adjoining segment 16.
In manhole 11 the guide mechanism 7 is mounted on the rod 5 and is inserted
into the sewer pipe 2. Subsequently the cutter head 6 is mounted
twist-proof and tension-proof on the free end of the rod 5, for example
with other crossbolts 17. The cutter head 6 comprises a hollow cylindrical
hub 22 and a conical jacket 23. Several cutting tools 24 are mounted in
the jacket 23. The cutting tools are indicated in FIG. 1 as double
conical, pivotable rollers 25 coated with hard metal or diamond on the
periphery, as known from drilling machines for tunnelling in mining.
Depending on the material to be worked, standing tools can also be
employed. The jacket 23 has several openings 26 to convey the worked
material. A hub 27 of a circular cylindrical, tubular shield 28 can be
pivoted on the hub 22 but is mounted thereon immovably longitudinally.
Shield 28 and hub 27 are connected together by way of spokes 29. The outer
diameter of the shield 28 corresponds to the outer diameter of the jacket
23 and is negligibly larger than the outer diameter of the new pipe 8.
The guide mechanism 7 includes a bearing body 33, in which the rod 16 can
be rotated, and to which four rollers 34, which are designed as support
elements and are distributed over the circumference, are attached radially
moveably. The rollers 34 are braced against the pipe 2. The position of
the rollers 34 can be controlled. Thus, the axis of the cutter head 6 can
be adjusted horizontally and vertically relative to the axis 35 of the
pipe 2. The adjustability of one pair of rollers 34 is merely indicated
diagrammatically by pressing the one roller 34 radially to the outside by
means of a leaf spring 36 and the opposite roller 34 is radially
adjustable by means of a double armed lever 37 and a hydraulic cylinder
38.
Such adjustment can be automated, for example, by means of laser telemetry
or also optically, so that any eventual sinking or shifting of the pipe 2
can be compensated for. An annular distributor pipe 39 with a wreath of
injection nozzles 40 adjacent to the cutter head 6 can be mounted on the
bearing body 33. The nozzles 40 are directed against the cutting tools 24.
Water is admitted into the pipe 39 by means of a hose 41.
The rear end of the shield 28 has a cylindrical extension 44 with reduced
outer diameter and a cylindrical countersinking 45 to receive sealingly a
cylindrical projection 46 of a pipe segment 47 of the new pipe 8 to be
pulled in, such pipe segment being called a press pipe. Both ends of each
pipe segment have a projection 46. A steel ring 48 is slid over two
abutting projections 46 in order to seal and center the same. A ring 49
with a diagonal brace 50, which is connected rotatably to the hub 22 or
the rear end of the pull rod 5 by way of a pull element 51, is inserted
over the projection 46 of the rearmost pipe segment 47, projecting into
the manhole 11. A socket 52, which is connected to the manhole 11 by way
of a hose 53, is welded to the extension 44. The pipe 12 of the manhole 11
is sealed relative to the rearmost pipe segment 47 by means of a sealing
ring 54.
The drive 3, 4 installed into the manhole 10 has a base plate 60, which is
braced against the pipe 12 of the manhole 10 by way of buffer 61 (e.g.
made of rubber). The plate 60 can also be strut-braced to ensure
anchoring. A prismatic, many sided extension 62, extending in the
direction of the axis 35, is welded to plate 60 and has an axial,
continuous bore 63. A housing 64 can be slid longitudinally, but
non-rotationally on the extension 62. The housing 64 can be slid relative
to the plate 60 in the direction of the axis 35 by means of several
hydraulic cylinders 65 (or an annular cylinder) distributed over the
circumference. The housing 64 carries a hydraulic motor 66 with an output
gear 67, which mates with a gear rim 68 of a gearwheel 69, slid on the
front end of the pull rod 5. The gearwheel 69 is braced rotatably and is
centered on the housing 64. The gearwheel 69 transfers torque and axial
thrust by way of a two part bushing 70, both sides of a face of which are
toothed radially, to a ring 71, connected twist-proof and axially
immoveably, e.g. by way of other crossbolts 17, to the front end of the
pull rod 5.
During service the hydraulic motor 66 and the cylinders 65 are pressurized
with pressurized oil, so that the cutter head 6 is rotated by way of the
rod 5 and is pressed against the front end of the pipe 2 to be replaced.
This pipe end and the enveloping stone, dirt and any concrete are
comminuted by the cutting tools 24. The worked material is then flushed by
means of water from the nozzles 40 through the openings 26 and between the
spokes 29 into a new pipe 8 and through this new pipe into the manhole 11.
The pipe 8 is subsequently pulled in by means of the pull element 51. To
hold the requisite forces to a minimum, an injection medium of
approximately the same specific weight as the surrounding soil is injected
by way of the socket 52 and the hose 53 into the narrow gap between the
outer wall of the pipe 8 and the bore produced with the cutter head 6. A
suitable injection medium is, e.g., a bentonite-cement suspension.
Bentonite is a ground opaline clay, which with water forms a specifically
relatively heavy emulsion, which remains liquid for a prolonged period.
The injection medium prevents the bore wall from caving in, because the
pressure prevailing in the soil and the pressure gradients can be held low
with such injection medium. Thus, the new pipe 8 floats to a degree in the
injection medium, as long as it has not yet cured and can be subsequently
pulled in with low forces while the cutter head 6 is advancing.
When the stroke of the cylinders 65 is exhausted, the housing 64 is moved
back against the plate 60 to an opposite stop and a longer or an
additional bushing 70 is inserted. This process is repeated until the next
separating point between the rod segments 16 in front of the gearwheel 69
is reached. Then the ring 71 is changed over to the next segment 16 and
optionally another pipe segment 47 is attached to the rear end.
To facilitate the expansion of the guide mechanism 7 and the cutter head 6
following entry into the manhole 10, it can be expedient to design the
base plate 60 and the housing 64 so as to be dismountable along a plane
containing the axis.
In contrast, with the design of the invention modest forces are necessary
to advance the new pipe 8, so that that stroke drive 4 can be small and
light-weight. Therefore, the drive 3, 4 can be built so small that it fits
in a normal sewer manhole 10, 11 that is present in any event. With the
solution according to the invention it is also hardly necessary to lift
the material to the street surface, so that an obstruction to traffic and
the work preparation time can be drastically reduced.
Because with the device of the invention the cutter head 6 is guided by
means of the guide mechanism 7 in the pipe 2, the conical front side of
the cutter head is self-centered relative to the cutting tools 24, as
compared to the state of the art. The danger that the cutter head 6 will
move diagonally to the pipe axis 35 is, therefore, virtually ruled out.
With the device according to the invention, the axis of the cutter head
with respect to the pipe axis 35 can be corrected in a simple manner and
with little effort by means of the guide mechanism 7 braced in the pipe 2,
resulting in virtually only the lateral offset, not the parallelism of
these axes, being relevant. In the state of the art, in contrast, the
cutter head is braced against a new pipe 8 that is forced in. Virtually
only the angle of the cutter head with respect to the axis of the new pipe
can be corrected, with the result that any lateral shift of the cutter
head that has already occurred frequently is hardly correctable at all.
Because in the device of the invention, as compared to the state of the
art, almost the entire cross-section of the pipe 8 that has been just
pulled in is free for transporting away the worked material, this material
can be flooded away in a very simple manner.
The device according to the invention is significantly smaller and less
expensive than known press pipe advancing systems. The work preparation
for replacement of a sewer pipe is drastically simplified, because there
is almost no need to lift to the surface. In contrast to the known
devices, the device according to the invention is also suitable for
pulling in relatively thin walled and correspondingly less expensive and
more commercially available pipes. Therefore, the use of the device
according to the invention is very economical.
In the embodiment according to FIGS. 3 and 4, analogous parts are provided
with the same reference numerals, so that a detailed explanation of these
parts is superfluous. The embodiment according to FIGS. 3 and 4 differs
primarily from those that according to FIGS. 1 and 2 due to the fact that
the rotary drive 3 is at the cutter head 6 and correspondingly the rod 5
is not rotated and the stroke drive 4 is designed differently.
The rod 5 is designed as a segmented rectangular pipe. The rearmost segment
80 has a front rectangular segment 81 and a cylindrical rear segment 82
with a thread lug 83. A housing 84 of the guide mechanism 7 is slid on the
segment 82, such housing reaching twist-proof over the segment 81. Here
the centering elements are, for example, three skids which are designed as
supporting elements and can be adjusted radially by means of a
piston-cylinder unit 86. Values (not illustrated) for controlling the
units 86 are built into the housing 84 and are activated by a controller
by way of an electric line 87 in response to measurement signals of a
laser device 88, which is disposed in the manhole 10 and scans a mark on
the front side 89 of the housing 84. Thus, the cutter head 6 is
automatically guided in a straight line.
In the housing 84 are attached two or, if necessary more, hydraulic motors
66, whose output gears 67 mate with the gear rim 68, attached here to the
cutter head 6. The cutter head 6 can be pivoted on a sleeve-shaped
extension 90 of the housing 84 and braced axially against the hub 27 of
the shield 28. The hub 27 is mounted with a nut 91 on the segment 82.
The stroke drive 4 comprises here a cable winch (not illustrated), which is
switched off at the bottom by way of the opening of the manhole 10 and
which pulls the housing 84 or the rearmost segment 80 toward the manhole
10 by means of a steel cable 92 over a guide pulley 93 mounted on the base
plate 60. Instead of this, the rod 5 can have teeth 94, with which a
pinion 95 of a hydraulic motor 96 attached to the base plate 60 meshes.
The base plate 60 has a rectangular opening 97, into which rectangular rod
5 is guided and by way of which the counter torque of the rotary drive 3
is transferred to the pipe 12 of the manhole 10.
The pull element 51 to pull in the new pipe 8 is also a steel cable. It can
be expedient not to connect this cable rigidly to the ring 49 (FIG. 2),
but rather by way of a cable line that can be operated, e.g. by hand. In
this case the new pipe 8 is not pulled along continuously, but rather is
pulled forward step-by-step. Thus, the stroke drive 4 for the cutter head
6 can be relieved of the force required to pull in the new pipe 8.
At variance with the embodiment shown in FIGS. 3 and 4, the rectangular rod
5 can also be disposed stationarily between the manholes 10 and 11 during
the advancing operation, wherein in this case the housing 84 of the guide
mechanism 7 has a continuous rectangular opening, which can be slid
longitudinally, but twist-proof on the rod 5. The extension 90 is not
longer and exhibits on the rear the correspondingly larger thread 83, and
the hub 27 is mounted on this extension 90. This variation has the
advantage that the advancing operation does not have to be interrupted to
work segments 16 in the manhole 10.
In both of the above described embodiments it is possible to ensure the
device during service against an eruption of ground water. To this end, a
somewhat pressure-tight partition is installed in the pipe 8 that has just
been pulled in. Another partition with a flexible rubber lip sealing
against the pipe 2 is mounted around the housing 84 of the guide mechanism
7. A sludge pump conveys away the wash water with worked material. A
compressed air line opens into the side of one of the two partitions
facing the cutter head 6. By supplying compressed air a pressure
corresponding to the ground water level is maintained in the space between
the two partitions. If the pipe 2 runs, for example, three meters below
the ground water level, an overpressure of about 0.3 bar would be
necessary.
The embodiments according to FIGS. 5 to 9 are especially suitable when the
material around the pipe to be replaced collapses easily. In such case the
friction to be overcome for the new pipe to be pulled in can be a multiple
of the axial force to be generated at the cutter head, despite the use of
washing agents. In such case violent pressing is necessary to advance the
new pipes, which are installed expediently in a pit in order to thrust the
new pipe into the cut bore.
In the embodiment according to FIG. 5, the sewer pipe 101, which is
defective or undersized, is to be replaced by a new and larger sewer pipe
102 on the same level. Pipe 102 is advanced starting from a manhole or pit
103 with a known hydraulic press device 104. At the front end a cutter
head 106 is braced axially against a ring 105 mounted on the pipe 102. The
cutter head is driven by way of a shaft 107 or directly by means of a
hydraulic motor 108.
The cutter head 106 has a journal 112. The journal 112 can be rotated in a
guide mechanism 113. The guide mechanism 113 can be adjusted radially by
means of at least two piston-cylinder units 114, 115 with respect to at
least two supporting elements with chucks 116. In this manner the cutter
head 106 is guided in the pipe 101 to be worked. The cylinders 114, 115
can be controlled, e.g. automatically by means of laser telemetry. In the
illustrated embodiment the two bottom cylinders 115, can set, e.g.,
periodically or continuously the guide mechanism 113 to the correct
eccentricity, optionally also to the correct tilt, whereas the upper
cylinders 114, 115 press with constant force of, e.g., one ton the two
chucks 116 against the wall of the pipe. In this manner a chatter-free
operation of the cutter head 106 is obtained. The chucks 116 extend as far
as the immediate vicinity of the cutter head 106 and extend in the shape
of a drum to the inner wall of the pipe. This is important especially when
the pipe 101 is reinforced with steel. In addition, it is expedient if for
different pipe diameters chucks 116, whose dimensions are correspondingly
different, or even sets of guide mechanisms 113 of different sizes are
used, so that the chucks rest uniformly against the inner wall of a pipe
101.
A rectangular pipe 121, assembled from segments 120, is screwed to the
front end of the guide mechanism 113. Analogous to the embodiment
according to FIG. 3, this pipe can be slid but locked against rotation in
a rectangular opening 122 of a hub 123 of a safety device against
rotation. The hub 123 can be pivoted in a bearing body 124 braced against
the wall of a manhole 110 and immoveably mounted in the axial direction.
An arm 125 is mounted on the hub 122, such arm can be adjusted by means of
a cylinder unit 126 around an axis 127 eccentrically to the axis 128 of an
new pipe 102, and the bearing journal 112 can be adjusted, therefore, in
two coordinate directions. Rectangular pipe 121 is used preferably for
calibration, provided prior to working, by mounting a cutter head, whose
diameter is approximately identical to that of the pipe to be replaced, on
the front side of the rectangular pipe, and the cutter head is pushed
through at a specific speed by means of rectangular pipe 121. The latter
is then already installed for working.
In FIG. 6 the positioning of the cutter head 106 is shown in somewhat
greater detail. The chucks 116 have, facing the cutter head 106, a rim 130
with cutting elements 138 (FIG. 8) with cutting edges, e.g. made of hard
metal, which interact with chisel-like working tools 131 of the cutter
head 106 in order to comminute the reinforced iron. The drive shaft 107 of
the cutter head 106 extends in an inner pipe 132 and carries a spiral
conveyor 133 to transport away the worked material. To reliably prevent
the guide mechanism from twisting, it is also possible to advance it
step-by-step while the cutter head 106 is standing still and to
subsequently press the chucks 116 firmly against the pipe 101. The cutter
head 106 is braced by way of an axial bearing 134 (merely indicated
schematically) against a ring 105 designed as a machine pipe. Such axial
bearing can be designed either in such a manner that the cutter head 106
can be freely moved radially relative to the ring 105, or depending on the
application, to guide the cutter head 106 radially on the ring 105.
FIG. 7 shows another embodiment, where analogous components have reference
numerals identical to the embodiment according to FIGS. 5 and 6, so that a
detailed description of these parts is superfluous. The embodiment
according to FIG. 7 differs from that according to FIGS. 5 and 6 primarily
in that the cutter head 106 is driven by a motor 150, which is arranged
directly behind the cutter head. The motor 150 is integrated in the ring
105 on the side of the spiral conveyor 107 and drives the cutter head 106
forward by way of a toothed wheel gearing 151. This design has the
advantage of being able to transfer more power through this direct drive
of the cutter head 106 than with an external drive.
FIG. 8 is a front view of the blade rim 130. As is apparent, the cutting
elements 138 of the rim 130 are distributed in a dense sequence over the
rim circumference. Cutting or shearing edges 139 have a variable slope
relative to the radial direction over the circumference, because the
cutter head 106 rotates eccentrically.
FIG. 9 depicts diagrammatically a front view of the cutter head 106 with
the chisel-like working tools 131, whose cutting and shearing edges 140
are arranged along spiral inlet edges 141 of three openings 142 of the
cutter head 106. The spirals 133 of the spiral conveyor shown in FIG. 6
attach to these inlet edges 141.
The pipe 101 to be replaced can be calibrated first so that the centering
head with the supporting elements 116 can be advanced along the entire
length of the pipe 1. During this calibrating operation any protrusions
projecting into the interior of the pipe 101, e.g. during lateral feeding,
are cut off with the cutter ring, which corresponds to the inner diameter
of the pipe 101 to be worked.
The present invention is explained with regard to the above described
embodiments. The guide mechanism could, of course, also be constructed in
a different manner, for example as a pilot bar which is rigidly connected
to the cutter head and which rotates in the pipe to be worked. The bar
could be calibrated to the effect that the front side of the pilot bar
includes an additional blade rim, with which in accordance with the
calibration any irregularities in the pipe would be removed simultaneously
during the working operation itself.
* * * * *
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Description |
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