1、BRITISH STANDARD BS4019-4: 1993 ISO3551-2: 1992 Rotary core drilling equipment Part 4: Specification for System A InchunitsBS4019-4:1993 This British Standard, having been prepared under the directionof the General Mechanical Engineering Standards Policy Committee, waspublished under the authorityof
2、 the Standards Boardand comes into effect on 15August1993 BSI06-1999 The following BSI references relate to the work on this standard: Committee reference GME/20 Special announcement in BSINews June1993 ISBN 0 580 22458 9 Committees responsible for this British Standard The preparation of this Briti
3、sh Standard was entrusted by the General Mechanical Engineering Standards Policy Committee (GME/-) to Technical Committee GME/20, upon which the following bodies were represented: British Coal Corporation Drilling and Prospecting International Limited English Drilling Equipment Co. Limited Instituti
4、on of Civil Engineers Institution of Mining and Metallurgy Natural Environment Research Council (Institute of Geological Science) Amendments issued since publication Amd. No. Date CommentsBS4019-4:1993 BSI 06-1999 i Contents Page Committees responsible Inside front cover National foreword iv 1 Scope
5、 1 2 Normative references 1 3 Designation 1 4 Materials 1 5 Dimensions and tolerances 1 Figure 1 System of dimensional identification letters 3 Figure 2 Drill rod and coupling 7 Figure 3 “W” design drill rod Drill rod tube 8 Figure 4 “W” design drill rod Drill rod coupling 9 Figure 5 General relatio
6、n of casing to core bit 10 Figure 6 Casing 10 Figure 7 Nesting of casing 11 Figure 8 “W” design flush-jointed casing Casing 12 Figure 9 “W” design flush-jointed casing Casing drive shoe 14 Figure 10 “W” design flush-jointed casing Casing shoe 15 Figure 11 “W” design flush-jointed casing Casing bit 1
7、6 Figure 12 “W” design flush-jointed casing Casing reaming shell 17 Figure 13 “X” design flush-coupled casing Casing tube 19 Figure 14 “X” design flush-coupled casing Casing shoe 20 Figure 15 “X” design flush-coupled casing Casing bit 21 Figure 16 “X” design flush-coupled casing Reaming shell 22 Fig
8、ure 17 “X” design flush-coupled casing Casing coupling 24 Figure 18 “WF” design double-tube core barrel Swivel type Assembly for sizes HWF, PWF, SWF, UWF and ZWF 25 Figure 19 “WF” design double-tube core barrel Short core bit 26 Figure 20 “WF” design double-tube core barrel Long core bit 28 Figure 2
9、1 “WF” design double-tube core barrel Core-lifter case 30 Figure 22 “WF” design double-tube core barrel Core lifter 31 Figure 23 “WF” design double-tube core barrel Reaming shell 32 Figure 24 “WF” design double-tube core barrel Outer tube 34 Figure 25 “WF” design double-tube core barrel Inner tube 3
10、6 Figure 26 “WF” design double-tube core barrel Head 37 Figure 27 “WG” design single-tube core barrel Assembly 39 Figure 28 “WG” design core barrel Single- and double-tube type Bevel wall core bit 40 Figure 29 “WG” design core barrel Single- and double-tube type Core lifter 41 Figure 30 “WG” design
11、single-tube core barrel Reaming shell 42 Figure 31 “WG” design single-tube core barrel Tube 44 Figure 32 “WG” design double-tube core barrel Assembly Rigidandswivel types 45 Figure 33 “WG” design double-tube core barrel Reaming shell 45 Figure 34 “WG” design double-tube core barrel Outer tube 48 Fig
12、ure 35 “WG” design double-tube core barrel Inner tube 50 Figure 36 “WG” design double-tube core barrel Head 52BS4019-4:1993 ii BSI 06-1999 Page Figure 37 “WM” design double-tube core barrel Assembly Swivel type 54 Figure 38 “WM” design double-tube core barrel Core bit 55 Figure 39 “WM” design double
13、-tube core barrel Core-lifter case 57 Figure 40 “WM” design double-tube core barrel Core lifter 59 Figure 41 “WM” design double-tube core barrel Reaming shell 60 Figure 42 “WM” design double-tube core barrel Outer tube 61 Figure 43 “WM” design double-tube core barrel Inner tube 62 Figure 44 “WM” des
14、ign double-tube core barrel Head 64 Figure 45 “WT” design single-tube core barrel Assembly Sizes BWT, NWT and HWT 66 Figure 46 “WT” design single-tube core barrel Reaming shell 67 Figure 47 “WT” design single-tube core barrel Tube 69 Figure 48 “WT” design double-tube core barrel Assembly Rigidandswi
15、vel types BWT, NWT and HWT 71 Figure 49 “WT” design core barrel Single and double type Bevel wall core bit 72 Figure 50 “WT” design core barrel Single and double type Core lifter 74 Figure 51 “WT” design double-tube core barrel Reaming shell 75 Figure 52 “WT” design double-tube core barrel Outer tub
16、e 77 Figure 53 “WT” design double-tube core barrel Inner tube 79 Figure 54 “WT” design double-tube core barrel Head 81 Figure 55 “WT” design double-tube core barrel Assembly RigidtypeRWT, EWT and AWT 83 Figure 56 “WT” design double-tube core barrel Bevel wall core bit 84 Figure 57 “WT” design double
17、-tube core barrel Straight wall core bit 85 Figure 58 “WT” design double-tube core barrel Core lifter 86 Figure 59 “WT” design double-tube core barrel Reaming shell 87 Figure 60 “WT” design double-tube core barrel Outer tube 89 Figure 61 “WT” design double-tube core barrel Inner tube 91 Figure 62 “W
18、T” design double-tube core barrel Head SizesRWT,EWTand AWT 92 Table 1 Identification symbols 2 Table 2 Mechanical properties 2 Table 3 System of dimensional identification letters 4 Table 4 Nomenclature and basic dimensions for drill rods and casings and their related diamond set items 5 Table 5 Nom
19、enclature and basic dimensions for core barrels and their related diamond set items 6 Table 6 “W” design drill rod and coupling 7 Table 7 “W” design drill rod and coupling 8 Table 8 “W” design drill rod and coupling 9 Table 9 Casing and casing coupling (where used) Main dimensions 11 Table 10 “W” de
20、sign flush-jointed casing 13 Table 11 “W” design flush-jointed casing 14 Table 12 “W” design flush-jointed casing 15BS4019-4:1993 BSI 06-1999 iii Page Table 13 “W” design flush-jointed casing 16 Table 14 “W” design flush-jointed casing 18 Table 15 “X” design flush-coupled casing 19 Table 16 “X” desi
21、gn flush-coupled casing 20 Table 17 “X” design flush-coupled casing 21 Table 18 “X” design flush-coupled casing 23 Table 19 “X” design flush-coupled casing 24 Table 20 “WF” design double-tube core barrel 27 Table 21 “WF” design double-tube core barrel 29 Table 22 “WF” design double-tube core barrel
22、30 Table 23 “WF” design double-tube core barrel 31 Table 24 “WF” design double-tube core barrel 33 Table 25 “WF” design double-tube core barrel 35 Table 26 “WF” design double-tube core barrel 36 Table 27 “WF” design double-tube core barrel 38 Table 28 “WG” design single-tube core barrel 40 Table 29
23、“WG” design single-tube core barrel 41 Table 30 “WG” design single-tube core barrel 43 Table 31 “WG” design single-tube core barrel 44 Table 32 “WG” design double-tube core barrel 47 Table 33 “WG” design double-tube core barrel 49 Table 34 “WG” design double-tube core barrel 51 Table 35 “WG” design
24、double-tube core barrel 53 Table 36 “WM” design double-tube core barrel 56 Table 37 “WM” design double-tube core barrel 58 Table 38 “WM” design double-tube core barrel 59 Table 39 “WM” design double-tube core barrel 60 Table 40 “WM” design double-tube core barrel 61 Table 41 “WM” design double-tube
25、core barrel 63 Table 42 “WM” design double-tube core barrel 65 Table 43 “WT” design single-tube core barrel (BWT, NWT, HWT) 68 Table 44 “WT” design single-tube core barrel (BWT, NWT, HWT) 70 Table 45 “WT” design single- and double-tube core barrel (BWT, NWT, HWT) 73 Table 46 “WT” design single- and
26、double-tube core barrel (BWT, NWT, HWT) 74 Table 47 “WT” design double-tube core barrel (BWT, NWT, HWT) 76 Table 48 “WT” design double-tube core barrel (BWT, NWT, HWT) 78 Table 49 “WT” design double-tube core barrel (BWT, NWT, HWT) 80 Table 50 “WT” design double-tube core barrel (BWT, NWT, HWT) 82 T
27、able 51 “WT” design double-tube core barrel (RWT, EWT, AWT) 84 Table 52 “WT” design double-tube core barrel (RWT, EWT, AWT) 85 Table 53 “WT” design double-tube core barrel (RWT, EWT, AWT) 86 Table 54 “WT” design double-tube core barrel (RWT, EWT, AWT) 88 Table 55 “WT” design double-tube core barrel
28、(RWT, EWT, AWT) 90 Table 56 “WT” design double-tube core barrel (RWT, EWT, AWT) 91 Table 57 “WT” design double-tube core barrel (RWT, EWT, AWT) 93 List of references Inside back coverBS4019-4:1993 iv BSI 06-1999 National foreword This Part of BS4019 has been prepared under the direction of the Gener
29、al Mechanical Engineering Standards Policy Committee. It is identical with ISO3551-2:1192 Rotary core diamond drilling equipment System A Part2:Inch units, which was prepared by Technical Committee ISO/TC82/SC6 Diamond core drilling equipment, of the International Organization for Standardization (I
30、SO) and in the development of which the United Kingdom played an active part. To a large extent this Part of BS4019 has been based on BS4019-1:1974, which first was issued in1966 and subsequently revised and converted into SI units by the UK in1974 in cooperation with Canada and the USA and supporte
31、d by Australia and South Africa and based on a proposal to ISO for an International Standard. This Part of BS4019, together with BS4019-3:1993, supersedes BS4019-1:1974 which is withdrawn. In this Part of BS4019 all dimensions are in inch units and the purpose of this Part is to provide, on an inter
32、national basis, the dimensional interchangeability in essential rotary core drilling fittings. These fittings are designed specifically for drilling with water as the circulating medium and are not necessarily suitable for use with air or mud as the circulating media. It is proposed to produce other
33、 Parts of this standard to cover equipment for use with air flush and wire-line, but it is not intended to publish British Standards on System B or System C. BS4019 comprises the following Parts: Part 3: Specification for system A. Metric units; Part 4: Specification for system A. Inch units. NOTETh
34、e title of the ISO standard is Rotary core diamond drilling equipment. However, the use of other cutting materials is permitted (see note to clause1). The Technical Committee has reviewed the provisions of ISO5864 and API7, to which normative reference is made in the text, and has decided that they
35、are acceptable for use in conjunction with this standard. A British Standard does not purport to include all the necessary provisions of a contract. Users of British Standards are responsible for their correct application. Compliance with a British Standard does not of itself confer immunity from le
36、gal obligations. Cross-references International standard Corresponding British Standard ISO263:1973 BS1580 Specification for unified screw threads Parts1 and Part2:1962 Diameters : in and larger (Technically equivalent) Summary of pages This document comprises a front cover, an inside front cover, p
37、agesi toiv, pages1to94, an inside back cover and a back cover. This standard has been updated (see copyright date) and may have had amendments incorporated. This will be indicated in the amendment table on the inside front cover.ISO3551-2:1992(E) BSI 06-1999 1 1 Scope This part of ISO3551 establishe
38、s the nomenclature and lays down the leading dimensions to ensure interchangeability within the limits of System A of the following equipment: a) drill rods and couplings; b) casings, casing couplings, casing bits, casing shoes, drive shoes and casing reaming shells; c) core barrels, core bits, core
39、 lifters and reaming shells. It specifies the characteristics of a range of equipment for drilling holes having diameters from1.18 in to7.88 in and yielding cores having diameters from0.73 in to6.5 in. NOTEThe title of this part of ISO3551 specifies diamond core drilling, but it is also possible to
40、use other cutting materials. 2 Normative references The following standards contain provisions which, through reference in this text, constitute provisions of this part of ISO3551. At the time of publication, the editions indicated were valid. All standards are subject to revision, and parties to ag
41、reements based on this part of ISO3551 are encouraged to investigate the possibility of applying the most recent editions of the standards indicated below. Members of IEC and ISO maintain registers of currently valid International Standards. ISO263:1973, ISO inch screw threads General plan and selec
42、tion for screws, bolts and nuts Diameter range0.06 to6 in. ISO5864:1978, ISO inch screw threads Allowances and tolerances. BS 1580:1962, Specification for Unified screw threads Parts1 and 2: Diameters1/4in and larger. API7, Rotary shouldered connection, internal flush type (IF). 3 Designation Items
43、manufactured in accordance with this part of ISO3551 shall be designated by its number followed by the symbols as listed in Table 1. 4 Materials Materials used in the manufacture of the equipment specified in this part of ISO3551 shall have the mechanical properties specified in Table 2, though for
44、special purposes other materials may be used by agreement between manufacturer and purchaser. The method by which the mechanical properties of tubes are obtained is left to the manufacturer. 5 Dimensions and tolerances 5.1 Dimensions All dimensions and tolerances shall be in accordance with Table 4
45、to Table 57. All dimensions given in this part of ISO3551, unless otherwise stated, are in inches (see Introduction). NOTE 1In System A, maximum and minimum values are included for all dimensions. NOTE 2All these items have a right-hand thread. Where a left-hand thread is necessary, it is stipulated
46、 for each individual case in the footnotes to the figure or to the corresponding table. NOTE 3The radius (or chamfer) of the thread crest and the radius in thread root corners are left to the manufacturers (determined by national standards of manufacturers countries). 5.2 Conformity When drilling in
47、 conformity with American Diamond Core Drill Manufacturers Association (DCDMA) and Canadian Diamond Drilling Association (CDDA) standards, the lengths of rods and casings shall be120in,60in or30in, but in those industries where drilling depths are measured in metres, the rod and casing lengths may b
48、e3m,1,5m or0,75m. 5.3 Eccentricity The eccentricity is defined as the distance between the centres of the outside and inside diameters andshall not exceed10% of the nominal wall thickness Q. The eccentricity is calculated according to the formulawhere Q maxand Q minare values of the wall thickness measured in the same section. 5.4 Straightness When measured over the whole length of the tube by rolling against a straightedge, the maximum deviation shall not be greater than1 in1200. Q max
