瑞典专利SE1351036A1 Drive clutch for lowering drill

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专利摘要:
A down-the-hole drill hammer is provided that includes a housing, a piston mounted within the housing, a drill bit mounted below the housing, and a drive coupling operatively engaged with the housing and drill bit. The drive coupling can be configured with a plurality of lugs circumferentially disposed about the drill bit and coupled with the casing for providing rotation thereof. Alternatively, the drive coupling can be configured with segmented lugs configured to circumscribe the drill bit, or as a cylindrical chuck formed out of arch-shaped chuck segments which radially assemble onto the shank of the drill bit.
公开号:SE1351036A1
申请号:SE1351036
申请日:2009-03-31
公开日:2013-09-09
发明作者:Leland H Lyon
申请人:Ct Rock Inc；
IPC主号:

专利说明:

Uï 10 15 20 FU During operation of such conventional drill bits, the piston of the submersible hammer hammer (driven by volumes of working air) striking the rear end 1189 of the shaft section llåü with a chuck (not shown) periodically engages in the grooves 1160 on the shafts 1160 on the shafts. horrkronan 1006 kring an central gesmetrisk axal. The working lock volumes are typically evacuated from the submersible hammer by rs n 1 suction pipe 2¿ the rear end of the shaft section 1140.
P O ä Such impacts on the rear anane 1189 of the skate section 1140 s occur inside the body of the main housing of the widow's hammer. Such shocks make the drill bit 1060 sensitive to elastic stress waves, which can lead to fatigue failure, due in part to elongated shafts of the shank 1140 and the aggressive cross-sectional change between the main section 1120 and the shank section.
The chuck, which is threadedly connected to the liner tubes liner tubes (not shown), operates by engaging the recesses 1169 on the shaft section 11 to provide the rotary tubes. However, the formation of the chuck leads to increased stresses created by the relatively small torque transmission diameter of the skating action 1140 compared to the main section 112 and due to the high intensity elastic strain the road passes through this local | J t »rM-J section with small diameters. Qetta lsaar ofte t 'i amràdat W a p a: Öl KI. firing ochßeíler kladdnisg of spàrnilgarna between the main action 1l2Ü ash chuckan, which can lay to accalararada fatigue brmtt man san kompanentfsl. Barcanda on the high torques applied by the chuck exercises that a relatively small surface area on the grooves 1168 can cause the chuck threads to get stuck on the countersunk hammer. The jammed chuck threads can make it extremely black and difficult to remove the chuck and / all the drill bit lßüü. Accordingly, there is a need for a low cost drill bit for submersible drills that is not limited by the problems associated with conventional submersible hammers.
BRIEF SUMMARY OF THE INVENTION Briefly, the present invention includes a submersible hammer that includes a cylindrical housing and a piston that is mounted inside the housing along a longitudinal direction.
The piston is coníigurexad to move forward and eats inside the housing along the longitudinal direction. The Sankbozxäammaren further includes a drill bit as well as anchored on the left side of the house. The crown includes a head, a scaffold extending from the head and a drive coupling which operatively slides into the housing and the drill bit.
BRIEF DESCRIPTION OF THE MULTIPLE - LIFE VIEWS IN THE RELATED PARTIES The following detailed description of the foregoing modes of presentation of the present invention will be read in conjunction with the accompanying drawings. 3e illustrating the invention is shown in the present invention which are presently preferred. The invention is not limited to the precise arrangements of the aids shown.
Pig l a pexsgekïivvy av a kenvenïionell drilling rig; Fig. 2 is a perspective view of a submersible drill bit (P CJ _ hot with a submerged position and without a sleeve in accordance with the preferred embodiment of the present invention; Fig. 3 is an enlarged partial perspective view of the discharge form of Fig. 2 with a lug removed; Fig. 4 is a pointed view). in cross section of the embodiment according to Fig. 2 with the drill crane in the abutment position eeh with an axle; in 10 15 20 35: Hiv is the ngsform. å-.J 'LU LO H FD FI ”DO íP * im: Fig. 5 an enlarged perspective view a according to Fig. Fig. 6 is an enlarged cross-sectional perspective view of the bearing of Fig. 5; Fig. 7 is an enlarged elevational side view of the bearing and lugs of the embodiment of Fig. Å in an assembled condition; Fig. 8 is an enlarged perspective view of the lugs of the embodiment of Fig. 4; Fig. 9 is an enlarged perspective view of the needle crown of the embodiment according to Fig. 4; Fig. 1 is a perspective view of a submersible hammamate in accordance with another preferred embodiment of the present invention, without a sleeve and without a segment d heel; Fig. 11 is a perspective view in cross section of the submersible hammer according to Fig. 10 with the sleeve and the segmented lug in an assembled condition; an enlarged perspective view of the sleeve of the embodiment according to rig 10, - Fig. 13 a partial elevational view from the side of the submersible hammer of the embodiment according to Fig. 10 without a liner; 1 is an enlarged perspective view of the layer of the embodiment Sig 10; Pig was an enlarged cross-sectional view of the layer according to ïig å; 16 is an enlarged perspective view of the segmented lugs of the embodiment according to Fig. 1%; Fig. 17 is a perspective view of a submersible hammer partially incorporated with liners in the present invention; 17a is an exploded view of the submersible hammer of Fig. 17%; rr] rxJ g; ig is another exploded view of the sledgehammer of Fig. 17A; Fig. 19 is an enlarged perspective view of a chuck segment of the submersible hammer according to Fig. 1a; Fig. 28 is a perspective view of a drill bit for the submersible hammer according to Fig. 17A; Fig. 21 is a partial perspective side view in cross section of a portion of the submersible drill bit of Fig. 17A; Fig. 22 is a top cross-sectional view in perspective of the submersible drill bit according to Fig. 17A taken along the unit à-R; and Fig. 23 is a partial perspective view of a pa ”.á sink hammer according to Fig. 17â without a casing.
DETAILED DESCRIPTION OF THE DRAWINGS Reference will now be made in the art to the present examples of the invention which are illustrated in the drawings. Wherever possible, the same or similar reference numerals will be used throughout the drawings to refer to the same or similar parts. Sets should be noted that the drawings are «in simplified form and are not drawn to exact scale. Regarding the description herein, for convenience, for the sake of clarity, for the sake of clarity, directional terms such as upper, lower, ever, lower, and diagonal are used with respect to the accompanying drawings. Such directional terms: used in conjunction with the following description of the drawings are not to be construed as limiting the scope of the invention in any way not expressly set forth. In a pre-drawn guide, the present invention provides a sledgehammer hammer, as shown in Figs. 2 to 9. The sledgehammer hammer includes a housing or tube: 12, a teon seal, a piston 16 and 4. » The drill pipe 12 has a generally hollow cylindrical configuration which allows the casing pipe to accommodate at least partially or completely the top closure 1 - ~ ä 3 Q šl H m (E) ¿* ._ 4 @ w H 14, the piston 16 and the drive coupling. With the further blanks, the lead pipe includes a cone Éâ which is less than 5 m HW ige in a section 25 formed with reduced diameter. Further down the spring pipe 12, the lead pipe 12 is configured with a connector, such as thread: 30 for inqxepp with the corresponding thread 32 on an enclosing sleeve 1% (Pig eel. ïid the farthest (fl 10 15 20 F.) UI u: CJ 35 end, the casing 12 is configured with a plurality of kiack recesses 23 to mow the remaining lugs 22a-c of the drive coupling l . X The present embodiment includes the plurality of clack recesses 23 and recesses 23a ~ c (only Z3b is shown in Fig. 3).
The top closure 1a may be a conventional conventional closure 14 which is suitably used in a submersible hammer.
The structure and function of such apertures are well known in the art, and a detailed description of the top closure 14 is not necessary for a complete understanding of the present invention. Seek discloses a luminous carpet closure 24 suitable for use in the present embodiment in U.S. Patent No. 12/361 2,300 adjacent to Rock, inc. U.S. Patent Application No. 12f36l 263 is hereby incorporated herein by reference in its entirety. Torque, compressive force, compressed air force and rotation are supplied to the submersible hammer 10 via the top fitting pipe fitting which connects to the submersible. The pivot and the rotation are passed on to the drill bit Bê by the x casing 12 itself, which is joined together but the top closure tube assembly 15, which suitably the piston 16 can be arbitrarily used in submersible drill shaft. The structure and function of such pistons are well known in the art and a detailed description of the piston is not necessary for a complete understanding of the present invention. However, a piston 16 suitable for use in the present embodiment is disclosed in U.S. Patent Application No. 12, 263. Later, the piston 16 is mounted within the liner tube 12 in the longitudinal direction and configured to move longitudinally within the liner tube. direction The drive coupling 17 includes a bearing 20, a plurality of lugs 22 (Pig ) and an enclosing sleeve and is generally configured to operatively engage the feeder tube 12 and the drill bit 14. Referring to Fig. 18, the sleeve 18 is a cylindrical sleeve configured by a connector 32, such as internal threads 32 around the axle end of the sleeve 18 for engaging the outer threads 30 on the contact end of the casing 12. The distal end of the sleeve 13 is generally configured so as to be integral. the lugs 22 when the integral lugs 22 are menïeraie at the submersible drill bit 16.
In addition, the outer end of the sleeve 18 is configured in Fig. 44 (see Fig. 9) by receiving the plurality of lugs 22 and the drill bit 2% when positioned in the shock position, as shown in Fig. 4. The sleeve 18 may optionally be be configured with a kena along an inner surface to provide a chemical fit.
As shown in Figs. 5 and 5, the bearing 2% has a generally hollow cylindrical configuration. The bearing 20 is dimensioned and shaped to fit inside the casing 12 so as to allow free passage for the piston 15 to pass through so that it can thereby receive a larger portion of the piston 16. The cavity 2U is retained near the distal end of the casing 12 by a stretching line. Ace 13 extending from the outer tube 12. Along the lower half of the bearing 20 along the outer surface of the shaft, an annular insert 3% is configured to engage an upper or upper flange 38 in Fig. 8) on each of the multilayer lugs 22. to prevent axial movement of the heels 22. Along the nedxe inneryian äx la Xoníiguxeraï with an annular ace 36 which extends redially inàï in relation to lagxeïs 2Ü v gg. A ring-shaped ridge for coexistence with the calf 36 for the purpose of evacuating air from the immersion chamber of the immersion chamber 1 (as shown in Fig. 4).
Q.
See further the lugs 22, as mentioned in the submersible hammer 10, are shown in Fig. 2. The further lugs 22 include lugs 22a ~ c, as best seen in Figs. 7 and 1Û 15 20 35 8. Alternatively, the submersible hammer 19 may be conjugated with more than three or less than three r. The lugs 22a ~ c are as shown in Figs. 7 and 8 and each 25b. generally configured one includes heel drives Zëa, Kring áe hiire ash bortxe the ends of var ech one of the heels 22s-c fians an »i« ~ .¿ annular íïäns 38, âü as ä: directed raaieila inward. Since the flange 38 on the lug 22a-c is configured to engage the annular insert bearing 2G, as shown in Figs. 7, 5 and 3, positioned inside the response of the clamping openings in the tube 12, the drill flange is longer than conical. reäad for u åsem -described below. With sliding engagement with the drill bit Éå, in other words, the distal lance åü gl wsnde connectors.long 2 iQ shaftsï àë of the drill bit- Kíeckerna Ze-C are also dimensioned and fastened with fitting inside the heel openings 46 in the drill bit 24. The heels 22a ~ c can optionally be comical, as best seen in Fig. 7, so that the lugs 22a ~ c can be easily clamped and secured at the bearing 2% with, for example, a sleeve 18.
Fig. 9 illustrates boron xenane 2% in a similarity with the present embodiment. The drill bit 24 is a one-piece constructed portion and configured with a head 42 and a 4% shaft extending from the head 42. The head is genere¿it kønfiguzeraï similar to the kenvenïienelía hood or shaving heads cm used in sink box hammers. The shaft yy is etï UI With other ers, the shaft yy has according to Lu: åg profile shaft. íeieïiggsnde utfäringsform píïegligi oxta: e lfsgd än kenventionella bmrrkrensskaft. Under set a conventional shaft crowns include a shaft having a longitudinal or axial longitudinal diameter of 3GO ~ 5OÜ% longer than the later axial length of the head, the axial length of the shaft being less than or S111 ". Uixka 200% of the axial length. of head 42.
Preferably, the axial length of the shell is less than about 190% of the axial length of the head 42. Depending on the diameter of an individual beam, 2% will be P4.
U] 20 the blow ratios between the axial lengths of the shaft êê and the head 42 to vary. The low profile ear crown 2% leoer with advantage for a reduction of about SG% elle: better of the total weight of the drill bit 24.
The shaft 4% is also configured with a V 'S3 PT' h; É Lä. l få 'ill Vi ff H (I) ”Ü (D 31' ful.
Get: (Ü WF * 45. The ílert liga klacköppningaïna åš c separate claw openings: áš which are configured to receive and intervene in the three respective kíaokaïna 22a ~ c. Each claw opening 46 has two oppositely located drive surfaces êâa, ëâb which can intervene in the corresponding heel drive surfaces Boa: espektive Zšb. The groove surfaces 48a, êšb are configured to have a single point contact surface which is s in conventional shaft grooves llšß.Gen simple point contact surface is defined as the contact surface at which a simple heel drive surface in eg heel drive surface 25a} g Preferably, the single point contact surface of the drive surfaces is approximately 25 times larger than conventional single point contact surfaces of shaft shafts 1150 and more preferably about âü% larger than 4.-. 1160. c is radially further outward than conventional so-called. radii outwards with oirka lš The drive surfaces ëâa, preferably the drívytoïna extend further or more ah conventional skittings 1169 and hellze about 25% or more than conventional shaft grooves 116.
Drivytoïna 48a, êšo is further coníigoreïa ﬁ e to have on to the cﬁtral axis of the submersible hammer 19 normal zvarenlttsarea which is larger than the transverse rivet area on conventional shaft cutsï 1163.
Preferably it is to the central axis of the submersible box hammers as .. 01) is a normal transverse axis of the drive surfaces f- 4 el: QX CD ÉZT. ëß cíïka had% relied on conventional shaft recessesï and rather cixka 5G% skate grooves larger than conventional 1166, C Drive surfaces Eêa, ﬁ öb of the heels Zâa- according to 10 l5 ZÜ 10 the present release form provides with íördel a substantially larger c surface area 22. apply a rotational force compared to the surface area provided on conventional shaft grooves 1159, thus reducing the possibility of firing and stresses at the point of contact. Preferably, a total diameter of the shaft 4% is substantially equivalent to the total diameter of the distal end of the spring tube 12.
Each of the lug openings âë includes a radially outwardly extending flange 52 formed around an upper end of the shaft 44. The plurality of claw openings å6 and the flanges 52 are configured to receive the distal flange ëü on the lugs 22aWc so that the distal flanges 4 % of each lug 22 can slide along the longitudinal wall of its respective lug opening äê. The flanges 52 also serve in part to secure the drill bit 24 to the rest of the submersible hammer.
The drill bit 24, which has such a basic profile or lag profile, advantageously reduces the stress transmitted to the drill bit 24 as a result of the striking movement of the piston bearing against the drill bit 24 so that a reduced profile of the shaft 4 * is reduced by other means. the elastic voltage waves experienced by the echo. In addition, as a result of the reduced stresses transmitted to the drill chuck 24, the chuck can be made of cylindrical pincer-shaped blank, such as a rod-shaped frame metal or wlegerlng, which is processed rather than forged material and an emideeproess. Qetta allows for reduced materials and manufacturing costs. Deeautem is the berr crane Zê entirely on the other side of the spring tube l2 and yet operatively connected to the spring tube 12.
F.
All in all, the sledgehammer hammer in accordance with the present embodiment provides a drive coupling which can minimize contact pressure on the shaft 44 while the shaft 44 has a cross-sectional area if! 10 20 35 11 maximized. In particular, the hammer drill 17 may provide a shaft 4ê with a larger diameter relative to conventional anchor hammer shaft sections (such as ll which there is a longer shaft section llê ﬁ), a mortar arm (L) on the shaft and a larger cross-sectional area. A shaft with a larger diameter can be realized as a direct result of the heel-driven drive coupling.
With reference to Fig., The submersible hammer is placed with the ash connected to the upper or few. ïapp closure ﬂ no la inserted the right end of the casing lä. The top closure l4 may be 'f .l ﬂ åf §w | connected to the casing with a threaded connection e on any other suitable connection. The knife 6 is positioned inside the casing 12 so that the piston 16 can move freely axially or longitudinally inside the casing 12.
At the lower or distal end of the casing 12, the bearing 20 is inserted into the casing 12 so that the hotter and one of the lugs 22a are attached to the rigid 3% of the bearing EU which is best seen in positioning the lower end of the casing. the lower flange å ﬁ on each of the lugs 22 "* - 'a» TW / A' “I '" h i'} _ "'*” "i'" ï “å * TV * [if Ü ﬁ * s loeltrcaeras inne 1 Å aenoyynlngaraa o. rerr. to be dlre “ti line with elastic stress waves which uçpætår during drilling, eliminates high axial electrical stresses along the drilling 24, improve manufacturing capabilities Gene.
During operation, when the piston 16 strikingly abuts the abutment surface Bá of the drill bit 24 held at or below the farthest UT 10 30, the drill bit 24 is displaced by This edge of the pipe 12, the lugs 2a ~ c engaging the lug openings ëß. advantageously leads ïill less fatigue stress on the shaft ëê, due to its shallow profile een relariït large drive surfaces, thus eliminating; áe problems som assecierade med conventioneíla: backar sem kàrver fesï på skaftepàrningar.
In another preferred embodiment of the present invention, the present invention holds a submersible drill bit lf, as shown in Figs. Referring to Eig EQ ash El, the countersunk hammer 109 includes a driver 112, a ring closure 114, a piston 316, a drive coupling ll and a crown of 12%.
The casing 12, the top closure 114, the piston 116 and the drill bit 124 are substantially the same as described in the previous embodiment. The present embodiment differs from the previous embodiment in the structure in the function of the coupling 117, which includes a sleeve 118, a bearing 120 and a plurality of segmented lugs 122.
As best seen in Figures 11 and 12, the sleeve 11 is a cylindrical sleeve configured on a mat in a plurality of self-cemented lacquers 122 and the drill bit. net dea s "re or ﬁ itre end includes the sleeve ll8 an inwardly extending šläne ll9 for engagement with a corresponding flame on the segmented lugs 122, as best seen in Fig ll. The length of ah 118 is generally configured ar moïra klac 'extensions í33a- 9 ﬁ ïig iö) of the ee cemented lugs 144 of the drill bit 124.
The bearing 320, as best seen in the cylindrical bearing 3 and can be shown in the farthest part of the piston 16. The bearing is also dimensioned and shaped to fit inside the cemented lugs 1a-c, as best seen in Fig. 13, and art meâge en ïrí passage för kolven llö att läpe igenøm. Around the nitre end of the bearing (_51 10 15 25 35 l3 l2O íinns an utàr radially sig srräcxande íläns lšë for a eraáe at FT mounting on or engagement with the sægmen q .. å fca Along the far end of the bearing 129 lan sin innæry gs _36 which protrude LW .. includes bearings 129 ën ringíormig äs ti in relation to the bearing wall.Ban ring-shaped radially inside the axis 136 cooperates mad kolvæn llš may create a venril šör to evacuate air from the submerged hammer hammer ﬂ ü ræturkammare 137.
Generally, the bearing is located near the far end of the feed tube 112.
The multilayer sieve-mounted lugs 122, as monied at the submersible hammer lßü, are best seen in Fig. 13. As shown in Fig. 1, the segmented lugs 122 are pre-configured as separate segments a, however, the plurality of segmented lugs 12 or more configured with than wood sawdust. The segmented lugs 222 ~ c are generally configurable as well as arcuate segmented lugs, for kind thereby forming a generally cylindrical drive lug when they are lined. Around the upper half or upper end of the segregated lugs l22a-C, the outer surface is sex-configured with connectors, so that threads 138 for connection with the liner tube 122. The threads l38 can connect to the liner tube llš gænøm so as hard is shown in Fig. ll. Around the far end 'of the sægmenäærade heels l22a-c there are äàgíormaàe heels all: klaskförlàngningar l23a ~ a which were san sn here árivyïcr ißêaï, l26a2, läâbl, lëöbï, lïöcl ræspaktivæ l , «» dimension passe formæ l , «» dimension 1-. f * Pâ: få Vi ”f) W drilling crown 12% on essentially the same säïr såsøm bæskrif 'utíöringsformen svan. Generellï är åe sagmanteradæ 122 køníiguræradæ att omskríva børrkrcnan lïâ. aa: and even of the arcuate lugs 123 a-Q also includes a radially inwardly extending distance ﬁ æ flame l25a-c åenbarr í25a man 135: shown in Fig. 16) which extends from the distal portions of the lugs l23a ~ c. 25a * c, the radially inwardly extending struts 10 are configured to slidably engage one of the integral lug openings 146 on the drill bit 12%.
As with the previous embodiment, the present embodiment provides a submersible hammer hammer which undergoes less total stresses, is less susceptible to fatigue failure, and is easier to maintain. Seeautam provides the present embodiment even with advantage a x-hammer hammer 199 which is simpler to xønstrukticaea and more robust as your result of scar fewer ststalt ant l a parts forming the drive coupling ll to sankborrhammaren lñü in n relation rill kønventionella sa kborrhammare.
In yet another preferred embodiment of the present invention, the submersible hammer 2C§ as shown in 175, 18, 21 comprises a piston Hig 1 A, The submersible hammer 260 includes a feed tube 212, Q-16, a drill bit 22â 2 and a drive ring 22â 2. . The submersible hammer QOÜ is similar in its general operation to the sam_aea according to the designation above. in other words, the calf 215 is maneuvered inside the feed tube 212 for reciprocating motion within the spring tubes 212 about a longitudinal direction, i.e., with the geomeric axis Ä. Briítan and driving mechanisms for moving the calf 216 ar kana ar kønïiqurerad sàsoe en chuckeunet 3l '.
Chuekenharen 217 'inåluáarar er: ílerral chuckeegmanï, så smm åre chuckaegment 222aMc, sàsam vzsea. Fia Nä. The chucksagmenï 222a ~ c is configured to monitor than in a cylindrical chuek 2 ;, As shown in moose 173. The chucksagmenïe éEQ is a generally hollow cylindrical check ash configured to feed and enable the passage of the bertre spirit of the calf 216 thereon. The chuck housing 217's ferrule may be the far end of the casing 212. The cylindrical chuck 222 includes a hot end 223 and a far end 226. The hot end 223 is configured with a connector 228. Preferably, the connector 228 is threaded dry bonding die 228 gets threaded engagement with the corresponding times 230 on the shoulder end of the spring tube 212.
Fëreträdeavis is the threaded connecting shape 228 configured along the outside of the cylindrical ehuck 222 for limbs * il QS 9 Û ”H É 7 DJ CI To thereby intervene in the corresponding row configured along an inside of the conductor tube Bla. The outer end 226 is configured to have a tetal outer diameter greater than the total outer diameter formed by the hot end 223. Preferably, the tetal outer diameter of the bar end 226 is substantially the same or greater than the total outer diameter of the outer end 226. the distal end of the casing 22 'As a result, the bristle 2 L. the end 226 of the cylindrical chuck 2 ° 2 is entirely on the underside of the casing 212. Referring to Fig. 19, an enlarged interior view of the chuck segment 222a is shown. Each individual chucre segment É t Éåâa, 222b, 222c, is configured as an arcuate segment of approximately É22a-c is * “° so that when each of the chucrse segments in. All. arranged side by side peripherally around the geometric axis in B, they form the cylindrical chuck 232. Also in the preferred embodiment, the cylindrical chuck 222 formed of three chuck segments c cylindrical 1 chuck 222 alternatively be configured by two or more chuck segments. , such as four or five eäuctsegments.
In the distal spirit 226 of the ehuck segment there are a plurality of chuck grooves 232 extending radially inwardly. each of the plurality of hucksters 232 is formed to engage in one of the four shaft shafts of H '6, further described below.
E 3 a ílertaliga chuckspårningaraa 237 finns att spår 23% sem är unfigurerat att mott en skaítepärning 256. Kring en äartre r »10 í5 IU CJ 16 .Tëqq ände av hver og og av chuoäspårningarna rr šinns oïï sträckanâe Flängparti 23 flänsparti 23 of the inwardly extending flange portions 238 extend radiiít in this year to thereby engage in extending flange portion 240 (Fig. 253 on the drill bit 224 and thereby retain the drill bit 224 inside the chuck 217 'when it is monied.
Generally, the distal end 22% of the cylindrical shock 222 is configured to oppose the akafïoï 24% of the crown 22. don the far end 226 of the oylinoric shock 222 258, inside there is a radially inwardly extending sträokanoe flange. The flange operatively engages in a pressure surface 256 çå a rearwardly facing surface "of cá skaíïet Eêâ, as described below. When oem is hopsart: ill the cylindrical .chucken 222 forms fíänëen 258 on essentially ka »circular flange surface which in a corresponding manner grips ir tryokytan 256. Üætta sar med fër ﬁ eï tili arr: ryckyran 256 ryms helt och häílot av och skyädas av chuokanhæton 2í *. onskiïÜa fl ( to bid don cylin ﬁ riska who k-. 222 of 1 :: ﬂ æn oylinàriska 1 ~ t kwš- I., 1 ß chucksegment gör det med foráeí mo ~ * a inåt sig rrraokande ï a J) chocken 222 i ett stycke bildar oo flänspartierna 23 % directly on the chuoksægmon In other words, the inwardly strëokanoe íšänspartiorna form a piece of locking mechanism for the drill bit. ivkopoíingarna Å sänkborrhammaro. ävom otï Chuokenhæten d 217 'ínklu och Gf ﬁ ï appears in Fig 173, 13 El. The bearing 2 “Ü is on gonorollc hollow cylinder for scars enable the passage üïâí then through and include a ra ﬁ iel 2 r eel around its hitro endæ. ßen toza ﬂ ë vïïro díamæïorn av C11 ÉG 15 20 17 legtets 229 body is keníiguxeted to be fitted in the hotter end of the cylindrical chuck 222, while the flange Eli is dimensioned to fit inside the feeer tube 212 as well as attach to the chucked end, As best seen in Fig. 21, the chuck unit 217 'may optionally include a chuck 218 as defined by the cylindrical senate 322. In a mentored condition, the chuck is attached to a distal end 226 of the cylindrical chuck 222, as shown in Fig. 21. The pressure washer 218 assists in assembly and maintains the cylindrical cylindrical configuration. a head 2â3 ash a shaft 24%. forward facing beer working surface 246 for a generally gone berry hole. äuvudet 2ê2 also has a tetal áiameter which is larger than the shaft Eëë.
The shaft Eêå is a low-frequency shaft- With change Grd, the longitudinal length of the shaft r along the geometric axis C is shorter so the length compared with kenventienelle berrkrensskeft.
EGO% of 1 rather less than Citta lsâ% ev the lensitudinal 242. less than about 242 and the length of the head shaft Eêé includes a plurality of spoons 236 circumferentially spaced around the shaft âåâ. Between the two shaft shafts 23% configured to receive one of the chuck grooves 232, the shaft shafts 235 are configured to operatively engage each other as shown in Fig. 22 of each side. a contact with a side edge 250 of a shank notch U: 10 15 20 25 35 18 single point contact surface that is larger than the kentect surface of conventional shank grooves: 1169. Gette depends in part on the larger total diameter of the shaft Rëš allowed since the size of the shaft Rëê is not limited by the iodine 212.
With the reference to Pig 29, each prediction is: 24 that its distant änüe spread: sig taàiell n tt outward bsrtre end 252 u derlätter a boxtbrutet matezial from ttänga into i eänkeerthemmeren EÜO.
In addition, formefna ech kenííg creates reticnezna av í ﬁ) 34 u skaftspàïningatna 236, chmekspär ﬂ ingerne 233 och epåzen, lá improved opportunities for weaving, such as the ability to make all kinds of cuts: in one step and improved tissue treatment, even cross-sectional cross-sections of all parts.
Preferably, each possible shaft is 24% ech the cylindrical chuck 222 configureïad meá nia eçåzningar. It has been discovered that nine corresponding sputations with the possibility of configuring the cylindrical chuck 222 and the shaft Záê with the greatest torque without appreciably causing kíadáning. Bock, can the number of epårnlngax for sxartet Såå and the cylindrical ckucken 222 know flex or fef ﬂ e than nine beïeende so the total støtle ﬂ a toe eänkbcrrhemmaren - = ä »_ e ..
¿. Around the hot shaft šåâ there is an outwardly extending ﬁ county party Zšü. Eet utåt sig sttäckende ílänspartiet Bäü extends ræeieílt utåt beyond track 247 longituàinelía yta, but not of the shaft pair 23%. The 249 is also 2š6. the direction of the drill bit Zëë u Pressure surface generally circular annular tr; É p ﬂ, š. 10 15 20 19 The abutment surface of the drill bit 25% is k @ ncenïïis <with the pressure surface 256.
The abutment surface 25% is slightly elevated planet in relation to the plane of the few pressure surfaces 256. The abutment surface 254 is the striking impact forces from the blade 216.
As best seen in Fig. 21, the outer end 223 of the cylindrical äuckæn 222: ill ﬁ æn børtre endæn of the fodder tube 21 ". The boxed spirit 22% of the cylindrical chuck 222 is, however, kva: ñælï and held on the other side of the far end. 22š av ëen syíindriska skafä Eêê och foderröret 212. chuckæn 222 koppla: tili b rxkïønan 22% via dess šär dan är howkøpplad 226 0 hysær med drillkronan 224 partiæílt. Kan borxkrwnan 22%: ära_siq axiell långan den cylreind 22 In use, however, the machining surface Záš mat is pressed to the bottom of the drill bit being drilled, * as a result, the drill bit 224 is pushed as far as possible up into the distal end 226 of the aylindic chuck 222, which thereby brings the pressure surface 256 into the ingress. bærkre änáän av dæn cyííndriska cbucken E2 (íïig lå). När drukyïan 56 ät i engræpp mad flänsen 258 blir anlagslag surface Ršâ kvar på hinsi ﬁ an am íoóerröræt 222, vlikket dåm ﬁ á pæsitionera: änsíagpunkten för kalven 21 6 under šødærröræt 212. Med anära avd bli: hæía bsrrïïmna ﬁ 22% kvar på hinsiáan om (ie uïanfëz) 222 ~ ta-a áiamætern av e nu _ y ~ - 2. -.-_ »- '> f'> ~" ﬂ, -. '<4 * _ _- x-M. ~ 2 :.
EILEISOÅTÄ GER iïtifïšfä * aïla ﬂ ššíï Lai ä Gmïï C “->,> Hx, ÛQS.J..S.-x: š Cíïíjigníw-EI) z L” f) is on hinsiüan if father the box tree end 22ö m bare end 22% intæ is ïø in other words inta dä äotala aimension: na av dan børtre enden fodærrözet å 226 bægränsade av de invàn ﬁ in ﬁ ﬁ imænsionæxæ ﬁ av 212. Since the farther greater, as a resuïïat the tatæla dimmeäern of skaítæt Råå can be carried sïöxre.
The set is for ﬂ elaktï efïersøm a thicker total diameter enables higher vridmsmænï. ”Æssuïom är av var ash æn av skafïspårningax 23ä sxörre än D 10 15 25 30 35 borehole diameter of the façade can be eaten,. ° l2. alternatively a _3 “is made equal to 'get A total diametexn of skaíts§àrnínf. the borehole diameter of the feeder tube includes a seal 5 :; The submersible hammer 200 ka The seal zuü 26G, whichever lift that can be shown can be a seal; so sam one. as a lufttäï í ﬂ g. The seal E ﬁ ê can be a polymer ﬁﬁ g, elastomer alle: çlasi. Tätn ngßn 269 is pes ﬁ ticnarad between 9 laqxæt 22Û ocä fodexröxæt _ as shown in Fig. 21.
E likhet meä utfëringsføxmærna Qvën tiíläandahåílur föræligående uïfözinqsíozm ﬁ ed fördêl en drivkoppling 217 som maximera: vrí'momænt på bazrkronan minimærar kantakïtry ﬂ k och af skaft med 224. en lower pïafï äi äil. conventional hammer drills. Q *. 224 pà sänkborxhammar ﬁ n EÛG mædan boïxkrcnan 22ê halds “à hínsidan om íoderröræt 332.
In summary, the present uïföïin ﬁ form and küntaktïryck go skaâtmt ¿êä with ~ maxi æras. Set äätaâkams shaft Éåâ mad major áiamæäer in íörhàlíande: išl konvænïí ﬁ nælla sänkbørrhammarskaíïsekåione; skaftsektiønæn lšêüi, áàršöx leads to a longer torque arm {L} on ækaítet ¿ê4 web than föï shaft Eêê cross-sectionïea åñxeasäankš. is made possible as a direct: result of a klackbaseïadæ kï ﬁ t drivkopplingæn. Senna ïördel can ﬁ ïïryckas såscm en 10 15 21 between the shaft's cross-sectional area (ax axhank), torque contact surface (A: æacontact}, sch mømeniarm §L} in relation to the applied rotary mømenïeï {T§ as defined by Quota 1 below.
Ratio 1: R = íâreashank X Azeaccntact X L)! T As defined by Quota 1, the present embodiment can provide a sinkhorxhammaïe asm has a kvøï R which is increased upy to cixka 2%% ella: mer.
Those skilled in the art will appreciate that changes may be possible from the forms of practice described above without departing from the broad inventive concepts thereof. It is to be understood that this invention is not limited to the particular embodiments described herein, but is intended to cover the modifications involved in any of the claims.

权利要求:
Claims (5)
[1]
1. A submersible hammer comprising: a housing; a piston mounted inside the housing and configured to reciprocate within the housing along a longitudinal direction; a drill bit near a distal end of the housing, the drill bit including: a head, and a shaft having a shoulder; and a segmented chuck unit defining the drill bit, the segmented chuck unit including: a plurality of chuck segments, each of the chuck segments including: a hotter end connectable to the housing, a distal end configured to receive the shank of the drill bit, and a flange which is configured to operatively engage the shoulder of the shaft.
[2]
The submersible hammer of claim 1, further comprising a bearing operatively connected to the housing and configured to receive a portion of the piston, the bearing including a flange around a higher end of the bearing configured to engage the segmented chuck unit.
[3]
Submersible hammer drill according to claim 2; in which the flange of the bearing is in direct contact with the segmented chuck unit and the housing.
[4]
A submersible hammer according to claim 1, in which the drill bit further comprises: a plurality of lug openings around a distal end of the shaft; and an abutment surface located near a higher end of the lug openings, in which the abutment surface is in operative engagement with and in direct contact with the flange of the segmented chuck unit
[5]
A segmented chuck unit for a submersible hammer comprising: a plurality of chuck segments defining a drill bit, each of the plurality of chuck segments including a hitter end connectable to a submersible hammer housing, a distal end configured to receive the drill bit, and a drill bit. is configured to operatively engage the drill bit.

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同族专利:

公开号 | 公开日

SE1051069A1|2010-12-07|

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CA2718669A1|2009-10-08|

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WO2009124051A3|2009-12-30|

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AU2009231791A1|2009-10-08|

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WO2009124051A2|2009-10-08|

SE538012C2|2016-02-09|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

US4081708P| true| 2008-03-31|2008-03-31|

PCT/US2009/038957|WO2009124051A2|2008-03-31|2009-03-31|Down-the-hole drill drive coupling|

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