US3613379A

US3613379A - Method for advancing tunnel supports

Info

Publication number: US3613379A
Application number: US836546A
Authority: US
Inventors: Joseph Donovan Jacobs
Original assignee: Individual
Current assignee: Individual
Priority date: 1969-06-25
Filing date: 1969-06-25
Publication date: 1971-10-19
Anticipated expiration: 1988-10-19

Abstract

APPARATUS AND METHOD FOR CONTINUOUSLY OR INTERMITTENTLY ADVANCING TUNNEL SUPPORTS AGAINST SURROUNDING EARTH PRESSURE. CUTTING EDGE AND TRAILING SHELLS ARE INTERCONNECTED BY A LONGITUDINAL FRAME OR CAGE STRUCTURE. INTERMEDIATE THE FORWARD AND TRAILING SHELL ARE OVERLAPING INTERMEDIATE SHELLS WHICH ARE INDIVIDUALLY CONNECTED TO THE CAGE STRUCTURE BY HYDRAULIC CYLINDERS SO THAT EACH INTERMEDIATE SHELL CAN BE MOVED LONGITUDINALLY RELATIVE TO THE OTHERS AND RELATIVE TO THE TUNNEL WALL WHILE THE OTHER INTERMEDIATE SHELLS ENGAGE THE TUNNEL WALL AND ADVANCE THE CAGE AS WELL AS THE FORWARD OR SUPPORT AND TRAILING SHELLS. THE INTERMEDIATE SHELLS ARE SEQUENTIALLY MOVED FORWARDLY, PREFERABLY BY RELEASING THE PRESSURE EXERTED AGAINST THE WALL, AS BY CONTRACTING THE SHELL OR BY PROJECTING THROUGH THE SHELL VARIOUS-SHAPED DEVICES WHICH GRIP OR PENTRATE THE WALL. THE SUPPORT MAY INCORPORATE STEERING GUIDANCE MEANS FOR ADJUSTING THE DIRECTION OF THE EXCAVATION DEVICE ABOUT PERPENDICULAR TRANSVERSE AXES. MEANS IS ALSO PROVIDED ON THE TRAILING SHELL FOR FEEDING OUT THE REARWARD END RIBBONS, OR ROD TO SUPPORT THE TUNNEL WALLS PRIOR TO CONCRETING AND ALSO A RETAINER SHELL WHICH FUNCTIONS AS A SCREED FOR THE CONCRETE AND SUPPORTS THE CONCRETE AS IT IS GAINING STRENGTH.

Description

Oct. 19, 1971 JACOBS 3,613,379

METHOD FOR ADVANCING TUNNEL SUPPORTS Filed June 25, 1969 5 Sheets-Sheet l INVENTOR. J. DONQVAN JACOBS ATTORNEY I 3 91+. w. I H I I I I I I W 0 IIIIIIIIFIIWI .TRII a III .III II III I. I .IIaI q I mm m w 8m &M 8m o N ll I'll] I I Illa N llllll I IW Pm I Q M. 1 1 1 I IIII W o m I N Q I Dw Mm \Iwi, mm M. I mv J m Tm wv INN Oct. 19, 1971 J. o. JACOBS "METHOD FOR ADVANCING TUNNEL s'urroms 5 Sheets-Sheet I Filed June 25. 1969 FIGS FIG-4 INVENTOR.

J DONOVAN JACOBS 6;; ATTORNEY Oct. 19, 1971 JACOBS $313,319

METHOD FOR ADVANCII iG TUNNEL SUPPORTS Filed June 25, 1969 5 Sheets-Sheet 4.

IIII II 103- 36b 31g 31h 101 311 31 104 106 29g 29h 29i 291 107 mvaw'ron. J. DONOVAN MACOBS BY I A ATTORNEY Oct. 19, 1971 J. 0. JACOBS 3,613,319

METHOD FOR ADVANCING TUNNEL SUPPORTS Filed June 25, 1969 5 Sheets-Sheet 5 United States Patent 01 fee} 3,613,379 Patented Oct. 19, 1971 3,613,379 METHOD FOR ADVANCING TUNNEL SUPPORTS Joseph Donovan Jacobs, San Rafael, Calif. Jacobs Associates, 500 Sausome St., San Francisco, Calif.

Continuation-impart of application Ser. No. 798,097, Feb. 10, 1969. This application June 25, 1969, Ser. No. 836,546

Int. Cl. E01g 3/00 US. Cl. 61-42 11 Claims ABSTRACT OF THE DISCLOSURE Apparatus and method for continuously or intermittently advancing tunnel supports against surrounding earth pressure. Cutting edge and trailing shells are interconnected by a longitudinal frame or cage structure. Intermediate the forward and trailing shell are overlapping intermediate shells which are individually connected to the cage structure by hydraulic cylinders so that each intermediate shell can be moved longitudinally relative to the others and relative to the tunnel wall while the other intermediate shells engage the tunnel wall and advance the cage as well as the forward or support and trailing shells. The intermediate shells are sequentially moved forwardly, preferably by releasing the pressure exerted against the Wall, as by contracting the shell or by projecting through the shell various-shaped devices which grip or penetrate the wall. The support may incorporate steering guidance means for adjusting the direction of the excavation device about perpendicular transverse axes. Means is also provided on the trailing shell for feeding out the rearward end ribbons, or rods to support the tunnel walls prior to concreting and also a retainer shell which functions as a screed for the concrete and supports the concrete as it is gaining strength.

This application is a continuation-in-part of co-pending application Ser. No. 798,097, filed Feb. 10, 1969.

A tunnel excavation device may be of various types, one common type having a rotary cutting or boring head containing wheels or knives or blades which cut or scarify the rock or earth at the face of the tunnel causing it to fall away from the face and thus creating the tunnel bore. Such device further incorporates means for picking up the material which is loosened and discharging the material onto a conveyor for ultimate disposal. In order to operate effectively, the excavation device must be forced against the tunnel face with tremendous pressure and this requires an anchor or support for the device. Previously used supports for this purpose have certain disadvantages. A principal object of the present invention is the provision of improved means for anchoring the tunnel excavation device so that it may be forced against the face of the tunnel with the requisite pressure.

A further principal effect of the present invention is that the tunnel excavation device is capable of advancing continuously, although intermittent advance is also possible. As a result, it is not necessary to discontinue the excavating action while the support is being moved forwardly and thus the present invention reduces the time required for excavation.

Another feature of the present invention is the fact that the support may be guided so that the excavation device will dig a curved path and the direction of the curve and, within reosonable limits, the radius of the curve is subject to considerable variation under the control of the operator.

Another principal feature of the present invention is the fact that the machine may operate in relatively soft ground where other tunnel boring head advancing equipment will not adequately grip the tunnel wall or face. Thus, as hereinafter explained in detail, a plurality of shells are brought into firm engagement wih the tunnel wall immediately behind the forward edge of the device and the combined effect of a plurality of such shells engaging the wall adequately anchors the machine and enables the device to be forced forwardly with the necessary pressure. In addition, the movable shells adequately support the tunnel wall until such time as concrete may be applied to the wall and provided sufficient time to set or other structural support installed.

Accordingly, still another principal feature of the invention is the fact that the machine supports the tunnel wall rearwardly of the excavation device against surrounding earth pressure for a sufficient distance so that a concrete lining may be applied to the tunnel bore and allowed partially to set. Thus, the invention provides structure for simultaneously advancing the excavating device and supporting in place the earth and rock behind the head.

Still another feature of the invention is the fact that a plurality of ribbons, wires or rods are fed out adjacent the rear of the machine in close proximity to the tunnel walls temporarily supporting the walls until a more permanent structural support can be applied.

Another feature of the invention is the provision of a space to the rear of the supporting means providing access to the tunnel wall so that concrete under pressure may be used to face the wall surrounding the ribbons, wires or rods which have heretofore been mentioned. 7 Still another feature of the invention is the provision of a trailing shell which follows the application of concrete and functions as a screed and also supports the concrete for sufficient time to enable it to begin to set.

One of the features and advantages of the invention is the provision of a concrete support which is moved continuously at the same speed at which the boring head advances in a continuous movement immediately behind the point of application of the concrete.

Other objects of the present invention will become apparent upon reading the following specification and referring to the accompanying drawings in which similar characters of reference represent corresponding parts in each of the several views.

In the drawings:

FIG. 1 is a vertical sectional view, partially broken away to reveal internal construction, of one form of machine in accordance with the present invention.

.FIG. 2 is a transverse sectional view taken substantially along line 22 of FIG. 1 in enlarged scale and partially broken away to conserve space.

FIG. 3 is a transverse sectional view taken substantially along line 33 of FIG. 1.

FIG. 4 is a fragmentary view of the intermediate shell expanding means as viewed substantially along line 4-4 of FIG. 2.

FIG. 5 is a fragmentary view of ahinge means for one of the steering rings as viewed substantially along line 5-5 of FIG. 3.

FIG. 6 is a fragmentary sectional view in enlarged scale taken substantially along line 66 of FIG. 3.

FIG. 7 is an enlarged fragmentary longitudinal sec tional view through a portion of the rear of the machine.

FIG. 8 is a fragmentary longitudinal sectional view through a'portion of the intermediate shells and surrounding structure.

FIG. 9 is a view similar to FIG. 8 of a modification.

FIG. 10 is a schematic view illustrating the method of the invention.

FIG. 11 is a fragmentary sectional view of a modified gripping device shown in retracted position; FIG. 11A shows same in projected position.

FIGS. 12 and 12A are views similar to FIGS. 11 and 11A, respectively, of a further modified device.

FIGS. 13 and 13A are views similar to FIGS. 11 and 11A of a still further modified device; FIG. 13B is a plan of aportion of FIGS. 13 and 13A.

FIGS. 14, 14A and 14B are views similar to FIGS. 13, 13A and 13B of another modified device.

The machine which is the subject of the present invention is installed as part of the equipment used to dig a tunnel having a face 21 which is here shown vertical and a tunnel bore 22 which is here assumed to be horizontal and circular in cross-section. The face 21 is continuously cut away usually by an excavating device (not shown) of a type commercially available such as, for example, a boring head disposed with the supporting structure 23 positioned immediately behind the face 21. As has heretofore been mentioned, the excavating device cuts or scarifies the tunnel face and the material displaced is collected and conveyed to the rear for disposal by means well understood in the tunneling art and not herein illustrated or described. Extending rearward from the rear of the support 23 is a cage structure 24 or frame which extends the entire length of the machine. Optionally, adjacent the rear of the cage structure 24 a trailing support shell 26 may be connected to the cage structure. It is a feature of the present invention that the support 23, cage structure 24 and trailing support shell 26 move together and it is a further feature of the invention that the same are capable of advancing continuously at a substantially uniform rate, although in some installations they may move intermittently An an optional feature of the invention, the cage structure 24 may extend rearwardly of the support shell 26 and be connected to a concrete retainer shell 27 which is of a lesser diameter to provide for the facing of the tunnel wall with concrete 28, all as hereinafter explained.

The cage structure 24 is anchored by a plurality of intermediate shell rings, 29a to 296 shown in FIG. 1 as five in number, each overlapping the adjacent rings and movable relative thereto and each articulately connected to the cage structure 24 by a plurality of hydraulic rams 31a to 31e. In a preferred method of operation of the invention, all of the intermediate shells 29a to e but one is anchored to the tunnel wall 22 and the rams 31 of the anchored shells are energized by hydraulic pressure to continuously force the cage structure 24 and accordingly the support structure 23 forwardly. The one shell 29 which is not anchored to the tunnel wall moves forwardly to the limit of the stroke of its ram 31, whereupon it is caused to be anchored to the tunnel bore 22 by means hereinafter explained in detail, and thereupon the next rearward intermediate shell 29 is disengaged from the tunnel wall and is moved forwardly until it abouts the shell which has preceded it. Each of the intermediate shells 29 is disengaged, advanced and re-engaged sequentially until the last of the intermediate shells 29c has been moved forwardly, whereupon the cycle is repeated with the forwardmost intemediate shell 29a being moved forwardly. Inasmuch as all but one intermediate shell 29 is firmly engaged with the tunnel wall 21, an effective means for anchoring the machine is provided which enables the cage structure 24 to be forced forwardly in the manner which has been described. At the same time, inasmuch as the intermediate shell 29 is individually sequentially being moved forwardly, the entire machine gradually advances, enabling the machine to move continuously rather than intermittently. Intermittent movement is contemplated as an alternate, however, The parts of the machine will be described in order.

The excavating support 23 comprises annular rings which are the cutting ring 36 which is at the front and has a diameter equal to bore 22, smaller diameter horizontal steering ring 37, the vertical steering ring 38 and the cage attachment ring 39. Ring 37 is within ring 36.

Rings

38 and 39 are enclosed Within shell 41 which is of the same diameter as cutting ring 36. The horizontal steering ring 37 and vertical steering ring 38 are articulated. In the means of articulation here illustrated, at the top and the bottom of the machine is a vertically disposed steering pin 42 and

eyes

43, 44 fixed to

rings

37, 38 and receiving pin 42 in oversize holes to permit relative flexing of the rings. As shown in FIG. 6, the arrangement of

eyes

43, 44 and pin 42 resembles an ordinary door hinge. Disposed within horizontal steering ring 37 on either side of the machine is a plurality of horizontal guidance cylinders 46, the rods 47 of which engage abutments 48 on the vertical steering ring 38. When the cylin ders 46 on the right-hand side of the machine are energized to project their rods 47 while those on the left-hand side are energized to retract their rods, the horizontal steering ring 3 7 tilts about the vertical axis of pins 42 to the left, thereby steering the cutting ring 36 to the left. If the opposite cylinders 46 are energized, then the machine is steered to the right. If both sets of cylinders 46 are at neutral, the machine steers straight ahead.

Between the vertical steering ring 38 and the cage anchor ring 39 on either side of the machine are transverse horizontal steering pins 51 which are received in

eyes

52, 53 similar to

eyes

43, 44 and affixed to the rearward faces of the vertical steering ring 38 and the forward face of the cage support ring 39, respectively. Mounted in vertical support ring 38 is a plurality of vertical guidance cylinders 56, some at the top and some at the bottom, the rods 57 of which engage abutments 58 on ring 39. When the cylinders 56 at the top of the machine are energized to project their rods 57 while the cylinders 56 at the bottom of the machine are energized to retract their rods 57, the machine tilts about a transverse horizontal axis through the axes of pins 51 to steer the cutting head downwardly. When the energization of the cylinders 56 is reversed, the machine steers upwardly, and when the cylinders 56 at top and bottom are equally energized, the machine advances horizontally.

It will be seen that selective energization of the

various guidance cylinders

46, 56 enables the machine to be steered to left or right or up or down, or that a compound curve may be generated. The

guidance cylinders

46, 56 enable the machine to be steered in accordance with a predetermined path and also to compensate for any tendency of the machine to drift out of the desired path.

Connected to cage support ring 39 is the cage structure 24. Extending longitudinally of the machine is a plurality of horizontal struts 61 e'qui-arcuately spaced around the perimeter of the cage structure. A plurality of transverse vertical cage rings 62a to 622 are connected to struts 61. The cage rings 62 are equi-distantly spaced longitudinally of the machine. The trailing support shell 26 is connected to the perimeter of the cage structure by brackets 63. Where a concrete retainer shell 27 is used, the struts 61 extend further rearwardly and there is at least one additional cage ring 62) and said shell 27 is connected to the struts 61 by brackets 64. It will be seen that ring 39, struts 61, intermediate cage rings 62 and shell 26 (and, where used, shell 27) are interconnected in a unitary structure.

In the form of the invention shown in FIGS. 2 and 4, each intermediate shell 29 is split along at least one 1ongitudinal element 66 and is further formed with a plurality of inwardly projecting strengthening ribs 67. Shell 29 may be made to expand and contract and in expanded condition the shell firmly engages tunnel wall 22 and movement longitudinally relative thereto is impeded by the frictional engagement of the surface of the shell with the tunnel wall. When the shell is contracted, the shell may be moved longitudinally relative to the tunnel wall. As has previously been mentioned, at any given instant, all of the intermediate shells 29 but one is expanded and in firm engagement with the tunnel wall, whereas one shell is contracted and moves relative to the wall to an advanced location. One means of expanding and contracting the shells is illustrated in detail in FIG. 4. One or more cylinders 68 is located bridging the split 66 in the shell perimeter, cylinder 68 being pivotally connected by pin 69 to bracket 71 fixed to shell 29 on one side of split 66 and rod 72 of cylinder 68 is connected by pin 73 to bracket 74 on the other side of split 66. When cylinder 68 is energized to extend rod 72, shell 29 is expanded and when cylinder 68 is energized in the opposite direction to contract the rod 72, shell 29 is contracted.

In the form of invention shown in FIG. 11, shells 29k do not expand and contract in the manner illustrated in FIGS. 2 and 4. Apertures 111 are formed at spaced intervals around the shells and within the shell immediately opposite such apertures are hydraulic cylinders I112 supported by brackets 1E3. The rods 114 of cylinders 112 may be extended through apertures 111 to penetrate or firmly engage tunnel wall 22k thereby anchoring the shell to the wall. As in the previous modification, one shell of series of shells is disengaged from the wall and this is accomplished by retracting rods 114 of that particular shell while all of the rods of the other shells are projected.

In FIG. 12. the ends 117 of rods 1141 are formed as conical points to penetrate the wall 22l.

In FIG. 13 square or rectangular pads 118 are attached to the outer ends of rods 114m and apertures 111m are shaped to accommodate same. The pads 118 when projected bear against the tunnel Wall.

In FIG. 14 pads l118n are circular and formed with a plurality of points 119. This form is particularly effective in rock or hard ground.

In other respects the structures of FIGS. 11-14 resemble the preceding modification and the same reference numerals followed by subscripts k, l, m and n, respectively are used to designate corresponding elements.

As best shown in FIGS. 1 and 8, shells 29 are formed so that they overlap. Thus the exterior of leading edge 76a of the forwardmost intermediate shells 29a is relieved at its perimeter by somewhat more than the thickness of the trailing edge of excavating support shell 41. At the trailing edge of the intermediate shell 29a the inner surface 77a is similarly internally relieved. Each of the intermediate shells 29b to 29e is constructed similarly to the leading intermediate shell 29a. To accommodate overlapping trailing support shell 26 and the last of the intermediate shells 292 the outer periphery 78 of the leading edge of the trailing support shell 26 is relieved. The individual shells 29 move forwardly at any given time a distance which is slightly less than the length of relief 76; hence at any instant the shells overlap.

Movement of the intermediate shells 29 is accomplished by energization of a plurality of peripherally spaced propulsion cylinders 31a to 31s. The rearward end of each propulsion cylinder 31 is pinned by pin 81 to the adjacent cage ring 62. The rod 82 of each such cylinder is pivoted by means of pin 83 to bracket 84 fixed adjacent theforward end of each intermediate shell 29. Thus each cylinder 31 is fixed to cage structure 24 and the position of each intermediate shell 29 relative to cage structure 24 depends upon the position of its rod 82 relative to cylinder 31. Preferably, all of the cylinders associated with a given intermediate ring 29 are energized equally and at the same time. Assuming that it is desired to advance the forwardmost of the intermediate shells 29a relative to the cage structure 24, it is assumed that there is a gap in the overlap of said shell 29a relative to shell 41 of structure 23 as is seen in FIG. 1 by exposure of relief 76a and shell 29a has been disengaged from the tunnel wall, the forwardmost cylinders 31a are energized to project their rods 82 and thus shell 29a is moved forwardly until the overlap is overcome. Thereupon shell 29a is caused to engage the tunnel wall 22. Meanwhile the next rearward shell 29b has been disengaged from the wall and each cylinder 31b is energized to advance said shell 2% to overcome the gap which has been created in the overlap between

shells

29a and 29b. This sequential disengagement from the Wall by shell 29, forward advance 6 and re-engagement of the wall is continuously repeated from front shell 29a to rear shell 29e and then renewed at front shell 29a. However, the energization of the propulsion cylinders 31 to advance the individual intermediate shell relative to the others is only part of the continu ous cycle of energization of said cylinders. Thus each cylinder 31 which is not immediately being used to advance an intermediate shell 29 is continuously being energized to retract its rod 82 relative to the cylinder 31. Since rods 82 are connected to the intermediate shells 29 which are in turn in firm engagement with the tunnel wall 22 and since the cylinders 31 are connected to cage structure 24, the contraction of rods 82 continuously forwardly advances cage structure 24. Forward advance of cage struc-- ture 24 pushes forwardly the support 23 for the excavating device and thus applies a continuous pressure on the device.

The fit between the individual intermediate shells 29 is such that they may twist relative to the longitudinal axis of the machine and relative to each other sufiiciently to follow the steering path of the steering mechanism of the boring head support structure 23.

An annular gap is maintained between the underside of relieved portion 77 at the trailing edge of each shell and the outer surface of each leading edge 76. Thus when a preceding shell 29 is in contracted condition its trailing edge does not impose pressure on the leading edge of the succeeding shell which prevents the contracted shell from moving relative to the expanded trailing shell.

Directing attention to FIG. 9, an alternate means for advancing the machine is disclosed. The intermediate rings 29x to 292 are articulately connected to adjacent rings rather than to the cage structure. Thus the rearward end of cylinder 31x is fixed by means of pin 81a to one of the reinforcing ribs 67a of intermediate rings 29y. Rod 82a is pivoted by means of pin 83a to one of the ribs 67a of the next forwardmost intermediate ring 29x. In

other respects, the structure of FIG. 9, is essentially the same as that previously described and the same reference numerals followed by subscript a are used to designate corresponding parts. However, in this structure, the advance of the boring head support 23 is intermittent rather than continuous. During such time as the forwardmost intermediate ring 29 is being advanced, advance of the boring head support ring is discontinued. When such forwardmost intermediate ring is in forward position and engages the tunnel wall, the forward progress of the boring head support 23 is resumed.

FIG. 7 shows a preferred means for feeding a plurality of rearwardly extending heavy wires 86, ribbons or small rods from the tail of the trailing support shell 26. Thus a plurality of reels 87 of said wire, ribbons or rods is mounted by means of shafts 88 which are connected by brackets 89 to struts 61. Suitable brakes (not shown) prevent over-travel of the unwinding of reels 87 and maintain the wires 86 or rods taut at all times. Longitudinal slots 91 are formed in the trailing edge of shell 26 for the egress of wires 86 and said wires are held in place near the periphery of the tunnel wall 22 by pulleys 92 mounted in brackets 93 at the slots 91. Hence the wires 86 extend rearwardly and are spaced closely enough together so that they prevent large rocks and debris falling into the tunnel behind the support ring 26. The term supporting material is used herein to include not only reinforcing wire 86 and rods but also ribbon, straps and flat sheets to perform a similar purpose. The space between ring 26 and screed 27 is used to apply concrete 28 to the tunnel wall and the wires support the wall 22 until the concrete 28 begins to set.

Screed 27 is of a diameter equal to the inside diameter of concrete 28 and its periphery serves to smooth the concrete as it moves forwardly. Furthermore, screed 27 supports the concrete for a period of time sufficient to enable it to gain strength.

It will be understood that other permanent or semipermanent structural supports for the tunnel bore may be applied in addition to, or instead of, concrete. For example, section metal shells may be inserted behind shell 290 or shell 26.

METHOD OF OPERATION Directing attention to FIG. 10, it will be observed that only four intermediate rings 29g to 29j are shown in order to emphasize that the number is discretionary and also to simplify explanation of the method of operation. Steering devices and other auxiliary features are eliminated for simplification. Cage 24 is represented by a single strut 101 having a cutting support member 36b at the front and a trailing shell 26 and four intermediate cylinder abutments 102g to 102j. The cylinders 31g to 31 bear against abutments 102g to 1021', while their rods 82g to j bear against brackets 84g to j on shells 29g to j respectively.

Vertical line 103 is a reference or datum line and does not represent the tunnel face except at the end of the completion of the cycle of operation illustrated. The cycle is shown in equal time intervals proceeding from top to bottom of the figure, the initial position being shown in sub-FIG. A and the last as sub-FIG. G; which is the same as sub-FIG. A except that strut 101 has advanced from tunnel face 21A to reference line 103. The increment of movement of member 36b per time interval is indicated by numeral 104, and a feature of the invention is the capability of advance continuously in equal increments per unit of time.

In FIG. A the vertical arrows on members 29g-j in dicate that these rings bear against bore 22b. Gap 106 exists between 29g and 36b; gap 107 between 29f and 26b (corresponding to shell 26 of FIG. 1). At this instant of time, none of the rings 29 is advancing. Note rod 82g is retracted, rod 82h projected one-fourth its travel, rod 821 one-half, and rod 82j three-fourths. Immediately after the instant of FIG. A, shell 29g is disengaged from wall 22b as has been previously explained.

FIG. 10B shows no vertical arrows on shell 29g indicating it is disengaged from the wall. The horizontal arrow shows shell 29g is moving to the left and has about reached the limit of its movement since gap 106 is about closed, whereas a gap 108 between

shells

29g and 29h has opened. In FIG. 10B rings 29/z-j are anchored against bore 22. Rods 8211, i and j have retracted equal amounts equal to distance 104, while rod 82g has projected. Thus strut 101 in the interval between FIG. 10A and 10B has advanced distance 104 toward reference line 103 by action of cylinders 31h to j and shell 29g has advanced the length of gap 106 toward reference line 103 by action of cylinder 31g. Immediately after the instant illustrated in FIG. 10B, shell 29g is caused to grip the wall and shell 29h to be disengaged.

FIG. 10 illustrates. therefore, the sequential gripping and release of shells 29 relative to bore 22. It also illustrates gradual extension of the rod-s 82 connected to shells 29 which are gripping to thereby gradually advance strut 101 and cutting ring 36!). Finally, it illustrates relatively rapid sequential advance of shells 29 Which are disengaged to eliminate the gap between said shells and the shell in advance thereof. The fact that the rods 82 are projected different distances at each time interval is likewise illustrated.

During most of the cycle of movement each shell is in gripping engagement and the combined effect of the shells which engage the wall is to anchor strut 101 against the thrust of the cylinders 31 advancing ring 36b. One shell 29, however, at almost every instance is disengaged and is moving forward relative to the others to close the gap ahead of it. When such gap is closed, that shell is caused to engage the wall and the next shell is disengaged and advanced.

Referring to FIGS. l-9, if it is necessary to change the direction of the excavating device in order to bring it back into a straight line or to cause it to travel on a curve, the

guidance cylinders

46 and 56 are used in a manner which has heretofore been explained, causing pivotal movement of ring 37 relative to ring 38 about the axes of pins 42 and of ring 38 relative to ring 39 about the axes of pins 51. Because of the fact that there is not a tight engagement of ring 41 relative to intermediate rings 29a, the two rings may twist slightly relative to each other so that they follow the necessary curvature, and the same relationship exists between the adjacent rings 29.

Where used, the wires 86, ribbons or rods are being continuously fed out through slots 91 at the trailing edge of the trailing support shell 26, lying in close proximity to the tunnel wall 22 and protecting the interior of the tunnel from falling rocks and large lumps of dirt. Concrete 28 is applied as soon as the trailing suport 26 has passed a given point. Modern pneumatic concrete sets up rather rapidly so that advance of the tunnel boring machine and the setting up of the concrete is substantially simultaneous. Screed 27 is drawn over the interior of concrete 28 to smooth the same and it also provides additional support while the concrete is gaining strength. 7

What is claimed is:

1. A method of supporting earth around the periphery of a bore wherein the forward end of an earth support is fixed for longitudinal movement with a member extending longitudinally of said bore with a plurality of boreengaging shells surrounding said member. said method comprising disengaging the first of said shells from the bore while engaging at least some of the other said shells with the bore, forcing said forward end and said member forward by pushing from all but said first shell against said member while pushing said first shell forward to the limit of its movement, engaging said first shell with the bore. disengaging said second shell from the bore while engaging at least some of the other said shells from the bore and forcing said member and said forward end forward by pushing while pushing said second shell forward to enga e said first shell and subsequently engaging said second shell with said bore.

2. A method according to claim 1, which further comprises individually sequentially expanding and contracting said shells, each said shell when expanded engaging said bore to resist sliding of said shell relative to said bore and when contracted being disengaged from said bore to per- "mit sliding of said shell relative to said bore.

3. A method according to claim 1, which further comprises individually sequentially with respect to each said shell extending a plurality of rods through said shell to engage said bore to resist sliding of said shell relative to said bore and then retracting said rods to permit sliding of said shell ralative to said bore.

4. A method according to claim 1, in which forward movement of said member and said forward end is substantially continuous.

5. A method according to claim 1, which further comprises steering said forward end by tilting said forward end about at least one axis transverse to the direction of movement of said member.

6. A method according to claim 1, which further comprises applying concrete to the rear of the last of said shells against the walls of said bore.

7. A method according to claim 6, which comprises substantially continuously discharging supporting material from the last of said shells to adjacent the walls of said bore prior to applying concrete.

8. A method according to claim 7, which further comprises securing the rearward ends of said supporting material in concrete which has set and braking the discharge of supporting material as said last of said shells advances so that said supporting material is maintained taut to support the tunnel against falling rock and debris while applying fresh concrete behind the last of said shells and allowing said fresh concrete to set.

9. A method according to claim '8 which further comprises pulling a screed a fixed distance behind the last of said shells inside said concrete and said supporting material to smooth the concrete and further support the concrete while setting, said fresh concrete applied between said last of said shells and said screed.

10. A method of supporting a tunnel wall comprising advancing a shell through a tunnel in close proximity to the tunnel bore, discharging supporting material behind said shell around at least a substantial portion of the periphery of said shell, applying concrete to the tunnel bore behind said shell to line the tunnel bore and also to secure the rearward ends of said supporting material after said concrete has at least partially set, braking the discharge of said supporting material from said shell to maintain said supporting material taut and thereby to support said tunnel bore against falling rock and debris, and applying fresh concrete immediately behind said shell While said tunnel bore is suported by said suporting material.

11. A method according to claim 10 which further comprises pulling a screed a fixed distance behind said shell inside said concrete to smooth the concrete and support the fresh concrete while it is setting, said fresh concrete applied between said shell and said screed.

References Cited UNITED STATES PATENTS 1,778,099 10/1930 Webb 61-84 UX 2,425,169 8/1947 Wilson 61-85 3,350,889 11/1967 Sturm 61-85 3,379,024 4/1968 Wohlmeyer 61-85 3,411,826 11/1968 Wallers et al. 61-85 X 3,487,649 1/ 1970 Bergstrom 61-85 FOREIGN PATENTS 1,205,928 12/1965 Germany 61-85 1,152,700 9/1957 France 61-84 DENNIS L. TAYLOR, Primary Examiner US. Cl. X.R. 61-84