Patent Publication Number: US-2012034376-A1

Title: Apparatus and method for applying a lubricant to a threaded portion of a steel pipe

Description:
TECHNICAL FIELD  
     This invention relates to an apparatus and method for applying a lubricant to a threaded portion of a steel pipe. More specifically, it relates to a lubricant applying apparatus and method suitable for application of a highly viscous (semidry type) lubricant to the surface of a threaded portion of a threaded joint for pipes formed on an end portion of a steel pipe, namely, to the surface of male (external) threads formed on the outer surface of the end of a pipe or to the surface of female (internal) threads formed on the inner surface of the end of a pipe. 
     BACKGROUND ART  
     Oil country tubular goods such as tubing and casing used for the excavation of oil wells are assembled to a necessary length in the field by successively connecting steel pipes each having a length of ten some meters by threaded joints. A threaded joint for pipes typically has a pin-box structure using a pin, which is a joint component having male threads, and a box, which is the other mating joint component having female threads. A coupling-type threaded joint which is typically used for connecting oil country tubular goods has a pin formed on the outer surface of both ends of a steel pipe constituting an oil country tubular good and a box formed on the inner surface on both sides of a separate short joint member referred to as a coupling. In some cases, an integral-type threaded joint for pipes in which a pin is formed on the outer surface of one end of a steel pipe and a box is formed on the inner surface of the other end of the pipe is used instead of a coupling-type threaded joint for pipes. 
     The depth of a usual oil well is 2,000-3,000 meters, but in recent years, the depth has reached 8,000-10,000 meters or more in deep wells such as marine oil wells. As a result, in the environment of use, a threaded joint used for connecting oil country tubular goods undergoes the stresses caused by an axial tensile force due to the weight of oil country tubular goods and the joint itself as well as combined internal and external pressures and heat. Therefore, it must be able to maintain gastightness without being damaged under such severe conditions of use. During the process of lowering tubing or casing into a well, a threaded joint which has once been tightened is sometimes loosened and retightened. According to API (American Petroleum Institute) standards, it is necessary for a joint to maintain gastightness without undergoing unrecoverable seizing referred to as galling even if tightening (makeup) and loosening (breakout) are carried out ten times for a threaded joint for tubing and three times for a threaded joint for casing. 
     There is a type of threaded joint for pipes having excellent gastightness under high stresses which is referred to as a premium joint and which can form a metal-to-metal seal. A premium joint has a threaded portion and an unthreaded metal contact portion on both a pin and a box. The unthreaded metal contact portions of the pin and the box directly contact each other and form a metal-to-metal seal having excellent gastightness. The unthreaded metal contact portion of the pin is constituted by a metal sealing surface positioned on the outer peripheral surface of the pin closer to the end than the threaded portion and a torque shoulder on the end face of the pin. Correspondingly, a metal sealing surface and a torque shoulder are also provided on the inner peripheral surface of the box. When the pin is inserted into the box and the threads are tightened until the torque shoulders of the pin and the box contact each other, the metal sealing surfaces of the pin and the box intimately contact each other with a predetermined amount of interference to form a metal-to-metal seal. A portion of the compressing load due to tightening is borne by the contacting torque shoulders, whereby the stresses acting on the threaded portions are decreased. 
     However, with a premium joint, galling easily takes place particularly in the unthreaded metal contact portions and particularly the metal sealing portions thereof, so lubrication is important to prevent galling. Up to now, a highly viscous greasy lubricating referred to as dope or compound grease has generally been applied prior to shipment to the threads and the unthreaded metal contact portions of a threaded joint for oil country tubular goods, which define the surfaces where the pin and the box contact each other at the time of makeup (referred to below simply as the contact surfaces of a threaded joint) with the object of increasing galling resistance and gastightness and protecting the contact surfaces against rusting up to the time of use. 
     In the case of a threaded joint for oil country tubular goods of the coupling type, in order to increase the roundness and the accuracy of the shape of the end surface of a long steel pipe and prevent fluid flowing inside the pipe from being disturbed at the surface where two members are joined to each other, a tapered recess (also referred to as a chamfer) is often provided on the inner surface of the pin adjacent to its end surface where it is joined to a box. Dope is also applied to the recess of the pin with the object of preventing rust. 
     Thus, on the end of a steel pipe which forms a pin, dope is applied not only to the outer surface and the end surface of the pipe which constitute a contact surface of the pin which contacts a box, but it is also applied to the inner surface of the steel pipe adjacent to the pipe end in which a recess is formed. A conventional dope called compound grease contains a large amount of powder of heavy metals such as Pb and Zn in order to guarantee lubricating properties and rust prevention (corrosion resistance). Application of dope is normally carried out by brush coating, namely, by putting a suitable amount of dope onto a contact surface of a threaded joint and then spreading it with a brush. 
     Below-listed Patent Documents 1 and 2 disclose a lubricant applying apparatus having a nozzle head which sprays a lubricant and a brush which spreads the sprayed lubricant as apparatuses for applying a lubricating such as a grease to a threaded portion of a threaded joint for pipes. 
     As a result of the enactment in 1998 of the OSPAR Convention (Oslo-Paris Convention) for preventing maritime pollution in the Northeast Atlantic, strict environmental regulations have been developed on a global scale. Particularly in North Sea oil fields, the use of lubricants containing heavy metals is prohibited in order to prevent marine pollution. Therefore, in the drilling of gas wells or oil wells on ocean rigs, there is a need to minimize the discharge of substances causing maritime pollution into the environment. For this purpose, it is a trend to require an assessment of the environmental impact of substances which could be discharged from rigs into the environment and prohibit the use of substances which do not satisfy the requirements of the country or region where drilling is taking place. Accordingly, in recent years, lubricants which can cope with such a demand are being developed. Such lubricants can be largely divided into solid lubricants which are not discharged into the sea at all (completely dry types) and highly viscous, high viscosity lubricants (semidry types) which have low toxicity even if they are discharged into the sea. 
     A completely dry type coating is typically a solid lubricating coating which comprises a lubricating powder dispersed in an inorganic or organic resin binder. This type of a lubricating coating does not have fluidity and has poor lubricating properties. This is because when it is subjected to a high pressure during makeup of a threaded joint for pipes, the coating is sometimes damaged, and galling takes place in the damaged portion. In contrast, when a lubricating coating formed from a semidry lubricant is subjected to a high pressure during makeup, the coating flows and moves around to locations where the lubricant is inadequate. As a result, it has excellent lubricating properties. However, since the lubricant which oozes out during makeup may possibly be discharged into the sea, a semidry type is inferior to a completely dry type from an environmental standpoint. Thus, a semidry type is advantageous when lubricating properties (galling resistance) are important. A semidry type which is superior with respect to galling resistance and gastightness is particularly suitable as a lubricant in the case of a premium joint which has a metal-to-metal seal having excellent gastightness but in which galling easily takes place in the metal-to-metal seal. 
     Patent Document 3 discloses a highly viscous lubricating coating composition having low toxicity (referred to below as “green dope”) which contains at least one basic oily lubricant selected from a basic sulfonate salt, a basic salicylate salt, a basic phenate salt, and a basic carboxylate salt and which has biodegradability (expressed as a value of BOD, biological oxygen demand) of at least 20% when measured after 28 days in sea water. Patent Document 3 also discloses that this lubricating coating composition may contain at least one other oily lubricant having higher biodegradability than the basic oily lubricant (preferably at least one substance selected from a fatty acid metal salt and a wax) and if necessary a volatile organic solvent. 
     The term highly viscous lubricant used herein means a lubricant having a viscosity which is too high to be sprayed as it is so that adjustment of its viscosity is necessary in order to make it sprayable. 
     Patent Document 1 JP 58-219964 A 
     Patent Document 2 JP 62-61667 A 
     Patent Document 3 US 2009/0264326 A1 
     DISCLOSURE OF INVENTION  
     With a conventional dope containing large amounts of heavy metal powder (compound grease and the like), only the minimum required coating weight was prescribed, and there was little need to strictly control the applied amount. Therefore, the necessary coating weight could be adequately guaranteed by brush application. 
     However, even though green dope has low toxicity, there is a demand to suppress the amount of lubricant which oozes out during makeup of a threaded joint for pipes as much as possible in order to minimize environmental pollution and particularly marine pollution. Reducing the amount which oozes out also improves the ease of makeup and the work environment. Therefore, the range for the coating weight of green dope is set to a considerably narrow range. Thus, when green dope is applied to the surface of a threaded joint for pipes, there is a demand that the applied amount be controlled so as to be as thin and uniform as possible within a range which can guarantee lubricating properties. 
     As the lubricant applying apparatuses disclosed in Patent Documents 1 and 2 both apply a lubricant to the pin and the box on the end of a pipe using a brush, there is a limit to how thinly and uniformly a highly viscous lubricant can be applied. A minute difference develops in the thickness of deposited lubricant between portions which are contacted by the hairs of a brush and those which are not contacted. In particular, the hairs of a brush strongly contact the ridge or crest of a thread so that the lubricant is worn and becomes thin. Furthermore, when performing application using a brush, there is a limit to how small the applied thickness can be made. Thus, in practice, it was impossible to apply a highly viscous lubricant like green dope to a thickness on the order of 10 μm or less, for example. 
     The object of the present invention is to provide an apparatus and method for applying a lubricant to a threaded portion of a steel pipe which can thinly and uniformly apply a controlled amount of a highly viscous lubricant having a high viscosity on the surfaces of a threaded portion formed on the end of a long steel pipe. 
     The present invention is an apparatus for applying a lubricant to a threaded portion formed on the outer or inner surface on the end of a steel pipe which constitutes a pin or a box of a threaded joint for pipes characterized by comprising (a) a steel pipe support unit which supports the steel pipe while rotating the pipe about its central axis, (b) a lubricant circulation system comprising a tank which stores a lubricant which has been adjusted so as to have a sprayable viscosity, piping through which the lubricant circulates, and a pump which forces the lubricant to circulate through the piping, (c) a metering unit comprising a metering pump in order to meter the feed of lubricant circulating through the lubricant circulation system, (d) a lubricant spraying unit comprising a lubricant feed passage for feeding the lubricant fed by the metering unit, an air feed passage designed to feed air for atomization independently of the lubricant feed passage, and at least one spray gun having a nozzle at its tip designed to spray lubricant at the outer or inner surface on the end of a steel pipe through the nozzle, the lubricant and air feed passages having a junction in the vicinity of the nozzle of the spray gun to atomize the lubricant, and (e) a spray gun support unit which supports the spray gun such that it can move in the axial and/or radial direction of the steel pipe. 
     Preferred embodiments of an apparatus for applying a lubricant to a threaded portion of a steel pipe according to the present invention include the following.
         The metering pump is a rotary plunger pump.   The spray gun support unit supports the spray gun so that it can be tilted with respect to the threaded portion of a steel pipe.   The lubricant comprises at least one basic oily lubricant selected from a basic sulfonate salt, a basic salicylate salt, a basic phenate salt, and a basic carboxylate salt and has a biodegradability (BOD value) after 28 days in sea water of at least 20%.   The viscosity of the lubricant is adjusted by diluting with a volatile solvent or by heating.   The tank has a stirrer for stirring the lubricant contained in the tank.   The apparatus further comprises a controlling unit for controlling the rotational speed of a steel pipe by the steel pipe support unit and the speed of movement of the spray gun by the spray gun support unit so as to satisfy the relationship given by Equation (1): V≦m×n×L wherein L is the length of the major axis (mm) of the sprayed pattern on the surface of the pipe of lubricant which is sprayed from the spray gun, n is the rotational speed (rpm) of the steel pipe, m is the number of nozzles in the axial direction of the steel pipe, and V is the speed of movement (mm/minute) of the spray gun by the spray gun support unit in the axial direction.       

     From another standpoint, the present invention is a method of applying a lubricant to a threaded portion formed on the outer or inner surface on the end of a steel pipe which constitutes a pin or a box of a threaded joint for pipes characterized by performing feeding lubricant and atomizing air separately to a spray gun having a nozzle at its tip, the lubricant having a viscosity adjusted so that it is sprayable and being circulating, mixing the supplied lubricant and the atomizing air in the vicinity the nozzle of the spray gun for atomization of the lubricant, and spraying the atomized lubricant at the threaded portion of the steel pipe from the nozzle of the spray gun while the spray gun is moved in the axial direction and/or the radial direction of the steel pipe and the steel pipe is rotated about its central axis. 
     According to the present invention, a highly viscous lubricant can be thinly and uniformly applied with a predetermined coating weight to a threaded portion of a threaded joint for pipes formed on the outer or inner surface on the end of a steel pipe, in particular to the surface of a pin which is typically formed on the end of a long steel pipe and which is difficult to coat. More specifically, a highly viscous lubricant can be uniformly applied to a thickness which is as small as 1/10 of a conventional thickness. 
    
    
     
       BRIEF EXPLANATION OF THE DRAWINGS  
         FIG. 1  is an explanatory view schematically showing the structure of an apparatus for applying lubricant to a threaded portion of a steel pipe according to the present invention. 
         FIG. 2  is an explanatory view showing the cross-sectional shape of a pin of a steel pipe. 
         FIG. 3(   a ) is an explanatory view schematically showing the state in which two spray guns spray a lubricant towards the surface of threads at right angles thereto, and  FIG. 3(   b ) is an explanatory view schematically showing the state in which two spray guns spray a lubricant at different oblique angles with respect to the surface of threads. 
         FIG. 4  is an explanatory view showing the state of spraying when spraying is carried out obliquely onto a thread. 
         FIG. 5  is an explanatory view showing an embodiment in which two spray guns having a spray angle different from each other are provided in positions which are circumferentially different from each other. 
     
    
    
     MODES FOR CARRYING OUT THE INVENTION  
     Below, embodiments of the present invention will be explained in detail while referring to the attached drawings. In the following description, unless otherwise specified, percent with respect to a composition means mass percent. 
       FIG. 1  is an explanatory view schematically showing the structure of an apparatus  1  for applying a lubricant to a threaded portion of a steel pipe according to the present invention. A steel pipe P such as an oil country tubular good (OCTG) or a riser pipe having an end  8  to which lubricant is applied has a male (external) threaded portion  8   a  on the outer surface of the end  8  and a female (internal) threaded portion  8   b  on the inner surface thereof. The male threaded portion  8   a  constitutes a pin of a threaded joint for pipes, while the female threaded portion  8   b  can constitute a box thereof. In the following description, the male and female threaded portions  8   a  and  8   b  are referred to as pin  8   a  and box  8   b,  respectively. 
     However, as is obvious to a skilled artisan, actually a box is not formed inside a pin at one end of a steel pipe P. A box is formed on the inner surface of a coupling, a separate member, in the case of a threaded joint of the coupling type or on the inner surface of the other end of a second steel pipe P in the case of a threaded joint of the integral type. Therefore, either pin or box is formed on one end of a steel pipe P. For the sake of convenience to show that a lubricant applying apparatus according to the present invention can be apply lubricant both to the pin and to the box of a threaded joint,  FIG. 1  is depicted so as to have a threaded portion on both the outer and inner surfaces on the end of a steel pipe P. 
     As described previously, on the inner surface of a pin of a threaded joint close to its end, namely, close to the end of a steel pipe, in place of a threaded portion as depicted in  FIG. 1 , a tapered recess (or chamfer) is formed (see  FIG. 2 ). A lubricant applying apparatus according to the present invention can apply lubricant not only to a pin or the outer surface on the end of a steel pipe but also to the recess which is often formed on the inner surface of the pin. Thus, a lubricant applying apparatus according to the present invention can apply lubricant not only to a threaded portion on the outer or inner surface on the end of a steel pipe but also to the other surface of the end of the pipe. 
     As shown in  FIG. 1 , a lubricating applying apparatus  1  comprises a steel pipe support unit  2 , a lubricant circulation system  3 , a metering unit  4 , a lubricant spraying unit  5 , a spray gun support unit  6 , and preferably a controlling unit  7 . These components will be explained in sequence. 
     [Steel Pipe Support Unit  2 ] 
     The steel pipe support unit  2  supports a steel pipe P having a pin  8   a  or a box  8   b  which is a threaded portion formed on the end of a pipe while rotating the pipe about its central axis in the direction shown by the arrow in  FIG. 1 . 
     In  FIG. 1 , turning rollers  2   a,    2   b  which support the lower portion of a steel pipe P and are drivingly rotated in the direction of the arrow in  FIG. 1  are used to constitute the steel pipe support unit  2 , but the present invention is not limited thereto, and any device which is known to have the same function as this type of steel pipe support unit can equally be used. Therefore, a further explanation of the steel pipe support unit  2  will be omitted. 
     [Lubricant Circulation System  3 ] 
     The lubricant circulation system  3  allows to circulate lubricant  9  which has been adjusted to have a viscosity suitable for spraying in order to stabilize the flow of the lubricant  9  and hence improve the uniformity of the discharge rate of lubricant  9  which is sprayed by the below-described lubricant spraying unit  5 . 
     The lubricant circulation system  3  shown in  FIG. 1  has a tank  10  which stores lubricant  9  having an adjusted viscosity so as to make it sprayable, piping  11  through which the lubricant  9  circulates, and a pump  12  for allowing the lubricant to run through the piping  11 . 
     The lubricant  9  which is used is one capable of forming a highly viscous (semidry) lubricating coating. Preferably, the lubricant is a green dope which has a minimized adverse effect on the environment even if it runs out. More preferably, it is a lubricating coating composition described in Patent Document 3 listed above. Namely, the lubricant  9  comprises at least one basic oily lubricant selected from a basic sulfonate salt, a basic salicylate salt, a basic phenate salt, and a basic carboxylate salt and has a biodegradability (BOD) after 28 days in sea water of at least 20%. 
     A means for adjusting the viscosity of a highly viscous lubricant so that it is sprayable may be either diluting the lubricant with a volatile solvent or heating the lubricant. An example of the composition of the lubricant  9  when it is diluted with a volatile solvent is petroleum solvent: 20-30% (a diluting solvent), petroleum wax: 5-10%, rosin: 5-10%, graphite: 3-5%, remainder: petroleum-derived basic calcium sulfonate salt (as a basic oily lubricant). An example of a lubricant having such a composition is commercially available under the tradename CWSD EVS from Daido Chemical Industry Co., Ltd. 
     The tank  10  is equipped with a conventional stirring mechanism  10   a  for stirring the lubricant  9  housed in the tank  10 . Stirring the lubricant  9  housed in the tank  10  with the stirring mechanism  10   a  serves to stabilize the composition of the lubricant  9  and hence improve the uniformity of the discharge rate of the lubricant  9  which is sprayed from the below-described lubricant spraying unit  5 . 
     The piping  11  has a three-way valve  13 , and one of the flow passages connected to the three-way valve  13  has a solenoid valve  14 . By opening the cock of the three-way valve  13  and suitably switching the solenoid valve  14 , the lubricant  9  which circulates through the lubricant circulating system  3  can be fed so as to apply either the pin  8   a  or the box  8   b.    
     [Metering Unit  4 ] 
     The metering unit  4  is provided for metered feed of lubricant  9  which has an adjusted viscosity and circulates through the lubricant circulation system  3 . It comprises a metering pump. In the illustrated embodiment, a rotary plunger pump is used as a metering pump, but any metering pump can be used as long as metered feeding of a sprayable viscous liquid is possible. 
     In the illustrated embodiment, the metering unit  4  is constituted by a first metering pump  4   a  for metered feeding of the lubricant to a first lubricant spraying unit  5   a  for applying lubricant  9  to the pin  8   a  (or the outer surface of an end of a steel pipe) and a second metering pump  4   b  for metered feeding of the lubricant to a second lubricant spraying unit  5   b  for applying lubricant  9  to the box  8   b  (or the inner surface of an end of a steel pipe). 
     The first metering pump  4   a  and the second metering pump  4   b  are both rotary plunger pumps which control the discharge rate of lubricant  9  in proportion to the rotational speed in order to control the feed rate of lubricant  9 . The discharge rate of the first metering pump  4   a  is controlled by a servo motor  4   c  and the discharge rate of the second metering pump  4   b  is controlled by a servo motor  4   d.  The uniformity of the discharge rate of the lubricant  9  which is sprayed by the below-described lubricant spraying unit  5  can be improved by controlling the discharge rate of the first metering pump  4   a  and that of the second metering pump  4   b  in this manner. 
     [Lubricant Spraying Unit  5 ] 
     In contrast to the lubricant applying apparatus disclosed in Patent Documents 1 or 2 which applies a lubricant to a pin  8   a  or a box  8   b  by spreading it with a brush, a lubricant spraying unit  5  in the present invention sprays atomized lubricant  9  at the pin  8   a  or the box  8   b  of steel pipe P. As described above, it has a first lubricant spraying unit  5   a  for applying lubricant  9  to a pin  8   a  and a second lubricant spraying unit  5   b  for applying lubricant  9  to a box  8   b.    
     The first lubricant spraying unit  5   a  has two spray guns  19  and  20  each having at its tip a nozzle  19   a  or  20   a  directed toward the pin  8   a,  lubricant feed passages  15   a  and  16   a  which send the metered lubricant  9  from the first metering pump  4   a  to the spray guns  19  and  20 , respectively, and air feed passages  17   a  and  18   a  which send air for atomization to the spray guns  19  and  20 , respectively, independently of the lubricant. The lubricant feed passage  15   a  or  16   a  and the air feed passage  17   a  or  18   a  merge at a junction (not shown) located in the vicinity of the nozzle  19   a  or  20   a  of the spray gun  19  or  20  to atomize lubricant  9 , and the atomized lubricant was sprayed from the nozzles  19   a,    20   a  towards the pin  8   a  of the steel pipe P. 
     Similarly, the second lubricant spraying unit  5   b  has a lubricant feed passage  21   a  through which metered lubricant  9  from the second metering pump  4   b  passes, air feed passage  22   a  which is independent of the lubricant feed passage  21   a  and through which air for atomizing passes, and a spray gun  23  which has a nozzle  23   a  at its tip for spraying lubricant  9  towards the box  8   b  of the steel pipe P. The lubricant feed passage  21   a  and the air feed passage  22   a  merge at a junction (not shown) located in the vicinity of the nozzle  23   a  of the spray gun  23  for atomization of lubricant and the atomized lubricant is sprayed through the nozzle  23   a.    
     In the illustrated embodiment, the lubricant spraying unit has one or two spray guns. It is possible to install three or more spray guns in the spraying unit  5 . Also in the illustrated embodiment, spray guns  19 ,  20  by which the lubricant is sprayed toward the pin are located in positions different only in the axial direction, but it is possible to locate spray guns in positions different in the circumferential direction or both in the axil and circumferential directions. 
     The first lubricant spraying unit  5   a  and the second lubricant spraying unit  5   b  both use air pressure to uniformly atomize the lubricant  9  which was adjusted in viscosity so as to be sprayable and then spray it towards the pin  8   a  or the box  8   b,  respectively, of the steel pipe P through the nozzles  19   a,    20   a,  or  23   a  which all can be opened or shut by air pressure. As a result, the stability of the discharge rate of lubricant  9  which is sprayed from the lubricant spraying unit  5  can be improved. 
     [Spray Gun Support Unit  6 ] 
     The spray gun support unit  6  has a mechanism for supporting the spray guns  19 ,  20 , and  23  so as to be able to move in the axial and/or radial direction of a steel pipe P. In the embodiment shown in  FIG. 1 , this unit  6  also has a mechanism for supporting spray gun  23  so as to be tiltable with respect to the surface of the box  8   b.  Although not shown in  FIG. 1 , the spray gun support unit  6  may further have a mechanism for supporting spray guns  19  and  20  so as to be tiltable with respect to the pin  8   a.    
     The spray gun support unit  6  has a first spray gun support device  24  for supporting spray guns  19  and  20  and a second spray gun support device  25  for supporting spray gun  23 . 
     The first spray gun support device  24  comprises a ball screw  24   a  for axial movement which is disposed above the steel pipe P and moves a support member  24   f  for the spray guns  19  and  20  in the axial direction of the steel pipe P, a servo motor  24   b  for axial movement which drives the ball screw  24   a  for axial movement, a base plate  24   c  on which the screw  24   a  for axial movement ball is mounted, a ball screw  24   d  for radial movement which supports the base plate  24   c  so as to be able to move in the radial direction of the steel pipe P, and a servo motor  24   e  for radial movement which drives the ball screw  24   d  for radial movement. The ball screw  24   d  for radial movement is secured to the front surface of a box shaped body  27  which can be moved backwards and forwards by an air cylinder  26 . 
     In this manner, the spray guns  19  and  20  are moveable in the axial and radial directions of the steel pipe P, and their amounts of movement and speed of movements are accurately controlled to desired values by the servo motors  24   b  and  24   e.  The positions of the nozzles  19   a  and  20   a  in the radial direction of the pin  8   a  of the steel pipe P, namely, the height of the spray guns  19  and  20  is set by the servo motor  24   e  such that the length of the major axis of the sprayed pattern of lubricant  9  on the surface of the pin  8   a  of the steel pipe P becomes a predetermined value L. 
     The second spray gun support device  25  is disposed towards the end of the steel pipe P. It has a ball screw  25   a  for axial movement which supports a support member  25   f  for the spray gun  23  in the axial direction of the steel pipe P, a servo motor  25   b  for axial movement which drives the ball screw  25   a  for axial movement, a base plate  25   c  on which the ball screw  25   a  for axial movement is mounted, a ball screw  25   d  for movement in the radial direction which supports the base plate  25   c  so as to be able to move in the radial direction of the steel pipe P, and a servo motor  25   e  for movement in the radial direction which drives the ball screw  25   d  for radial movement. The support member  25   f  is provided with a screw  25   g  which passes through it for adjusting the tilting angle of the spray gun  23  with respect to the surface of the box  8   b.  The ball screw  25   d  for movement in the radial direction is secured to the front surface of the box-shaped body  27  which can be moved forwards and backwards by the air cylinder  26 . 
     In this manner, the spray gun  23  is movable in the axial and radial directions of the steel pipe P, and its amount of movement and speed of movement are accurately controlled to desired values by the servo motors  25   b  and  25   e.  The position of the nozzle  23   a  in the radial direction of the box  8   b  of the steel pipe P, namely, the height of the spray gun  23  is set by the servo motor  25   e  to a position such that the length of the major axis of the sprayed lubricant  9  on the surface of the box  8   b  of the steel pipe P becomes a predetermined value L. 
     If the distance of nozzles  19   a  and  20   a  from the pin  8   a  or the distance of nozzle  23   a  from the box  8   b  is too small, there is the possibility of the nozzles  19   a,    20   a,  or  23   a  contacting the steel pipe P, while if the distance is too large, the sprayed lubricant  9  splatters and it may not be possible to obtain a desired coating thickness. Therefore, the distance is preferably as small as possible without producing interference of equipment. From this standpoint, the distance of nozzles  19   a  and  20   a  from the pin  8   a  and the distance of nozzle  23   a  from the box  8   b  are preferably 30 mm to 80 mm. The angle of spray of the lubricant discharged from the nozzles is preferably in the range of 5 to 15 degrees. 
       FIG. 2  is an explanatory view showing the cross-sectional shape of a pin  8   a  of a steel pipe P. 
     As shown in  FIG. 2 , a male thread (external thread) formed on the surface of a pin  8   a  has a thread crest surface  8   d  which is parallel to the outer surface  8   c  of the steel pipe P which forms a thread root of the male thread, a flank  8   e  (stabbing flank) which has an angle of slope of 10° with respect to a surface perpendicular to the outer surface  8   c,  and a flank  8   f  (load flank) which is angle of slope of −3° with respect to a surface perpendicular to the outer surface  8   c.  The angle of slopes of the stabbing flank  8   e  and the load flank  8   f  are mere examples and can be varied. The angle of slope of the load flank may be zero degrees or have a positive value. In the following description, the flank  8   e  which has a positive angle of slope is referred to as a P flank, and the flank  8   f  which has a negative angle of slope in the illustrated embodiment is referred to as an N flank. 
       FIG. 3(   a ) is an explanatory view schematically showing the state in which spray guns  19  and  20  spray a lubricant  9  at right angles with respect to the thread crest  8   d,  and  FIG. 3(   b ) is an explanatory view schematically showing the state in which the spray guns  19  and  20  spray a lubricant  9  at an oblique angle with respect to the thread crest. The arrows pointing to the left in  FIG. 3(   a ) and  FIG. 3(   b ) show the direction of axial movement of the spray guns  19  and  20 . The shape of a thread is the same as depicted in  FIG. 2 . 
     As shown in  FIG. 2 , the pin  8   a  has a thread shape having a P flank  8   e  with a positive angle of slope and an N flank  8   f  with a negative angle of slope. Therefore, as shown in  FIG. 3(   a ), when the spray guns  19  and  20  are oriented so as to be perpendicular with respect to the thread crest  8   d  when spraying the lubricant  9 , the lubricant  9  can be thickly applied to the surfaces of the thread root  8   c  and the thread crest  8   d,  but it is not possible to guarantee a sufficient coating thickness of the lubricant  9  on the surfaces of the P flank  8   e  and the N flank  8   f,  and the lubricant  9  can not be uniformly applied to the surface of the pin  8   a.    
     Therefore, as shown in  FIG. 3(   b ), by spraying the lubricant  9  with spray gun  19  which is sloped by 20-40° towards the end of the steel pipe P (towards the right in  FIG. 3(   b )) and with spray gun  20  which is sloped by 20-40° away from the end of the steel pipe P (towards the left in  FIG. 3(   b )) or from −20 to −40°, the thread root  8   c,  the thread crest  8   d,  the P flank  8   e,  and the N flank  8   f  can all be uniformly coated with the lubricant  9 . 
     This will be explained below more fully. As shown in  FIG. 4 , in accordance with the angle of spraying direction α (the angle of a spraying nozzle with respect to a surface perpendicular to the longitudinal axis of the steel pipe) and the shape of the thread (thread height and the sloping angle of the flanks), the sprayed lubricant strikes on a part of thread surfaces, and the remaining portion of the thread surfaces becomes a shadow on which the lubricant does not strike due to interference of the thread shape. In the illustrated example, the surfaces of the thread root and the P flank are shadows. When the angle of each surface of a thread with respect to the spraying direction varies, the projected area of the spray on that surface varies, thereby varying the coating thickness applied to that surface. 
     Upon further investigation in this respect, in the case of the thread shape shown in  FIG. 2 , each of the N flank and P flank has a shadowed portion on one side of zero degrees in which lubricant cannot be applied. It was found that by tilting the nozzle  19   a  of the spray gun  19  at an angle in the range of 20° to 40° and the nozzle  20   a  of the spray gun  20  located closer to the end of the steel pipe at an angle in the range of −20° to −40°, all the surfaces of a thread can be effectively applied with a nearly uniform coating weight. 
     When two spray guns (intended for application to a P flank and an N flank of a thread, respectively) in which the spraying directions of the nozzles are different from each other are used to apply lubricant to a male thread of a pin having a flank with a negative angle of slope from both sides of the thread for the purpose of uniform application, it is not preferable that the sprayed streams discharged through the two nozzles interfere with each other. As shown in  FIG. 5 , it is preferable that if two spray guns are located in positions which are the same in the axial direction (so as to apply lubricant to the same thread or orient their nozzles toward the same thread), they be arranged in positions which are different in circumferential direction such that the two sprayed streams impinging on the same thread do not interfere with each other. Thus, the two spray guns  19 ,  20  shown in  FIG. 3(   b ) which are oriented toward the two flanks of the same male thread are located in positions which are circumferentially different from each other, although it is not apparent from the figure. 
     In this manner, using the spray gun support unit  6 , the lubricant  9  having its viscosity adjusted so as to be sprayable is atomized by air pressure becomes a uniform mist and it is sprayed through the nozzles  19   a,    20   a,  or  23   a  which can be opened and shut by air pressure towards the pin  8   a  or the box  8   b  of the steel pipe P. 
     Instead of using the first spray gun support devicet  24  and the second spray gun support devicet  25 , it is of course possible to support the spray guns  19 ,  20 , and  23  using a general-purpose articulated robot, for example, whereby each spray gun can be tilted. 
     [Controlling Unit  7 ] 
     It is not always necessary to provide the controlling unit  7 , but it is preferable to provide it to stabilize spraying of the lubricant  9 . 
     The controlling unit  7  controls the rotational speed of the steel pipe P by the steel pipe support unit  2  and the speed of axial movement of the spray guns  19  and  20  or  23  by the spray gun support unit  6  so as to satisfy the following Equation (1): 
         V≦m×n×L    (1)
 
     wherein L is the length of the major axis (mm) of the sprayed pattern on the pin  8   a  or the box  8   b  (or on the surface of the steel pipe) of the lubricant  9  sprayed in a conical shape from spray gun  19 ,  20 , or  23 , n is the rotational speed (rpm) of the steel pipe P by the turning rollers  2   a  and  2   b,  m is the number of nozzles  19   a,    20   a,  or  23   a  in the axial direction of the steel pipe P, and V is the speed of movement (mm/min) of the spray gun  19 ,  20 , or  23  in the axial direction by the spray gun support unit  6 . 
     When there exist a plurality of nozzles having the same position in the axial direction of the steel pipe P but different positions in the circumferential direction thereof, these nozzles are considered to constitute a set and the number of m is made one. 
     The reasons why the controlling unit  7  preferably performs this function is as follows. 
     The lubricant applying apparatus  1  according to the present invention applies a lubricant  9  in a helical shape on a pin  8   a  or a box  8   b  of a steel pipe P by spraying a lubricant  9  having its viscosity adjusted so as to be sprayable in a conical shape on the pin  8   a  from nozzles  19   a  and  20   a  of spray guns  19  and  20  which move in the axial direction of the steel pipe P or from nozzle  23   a  of spray gun  23  on the box  8   b  of a steel pipe P while the pipe P is rotated in the direction of the arrow by turning rollers  2   a  and  2   b.  Therefore, if the speed of movement V of the spray guns  19 ,  20 , or  23  in the axial direction exceeds the above value (m×n×L), uncoated portions are intermittently formed in the axial direction of the steel pipe P between the helical coating. Conversely, if the speed of movement V of the spray guns  19 ,  20 , or  23  in the axial direction is too slow, productivity decreases, the applied thickness of the lubricant  9  becomes too large, and the lubricant  9  which was applied to the pin  8   a  or the box  8   b  may flow away. 
     The speed of movement V (cm/sec) of the spray guns  19 ,  20 , and  23  in the axial direction of the steel pipe P, the coating thickness W (cm) of the lubricant  9 , the overall feed rate of lubricant q (ml/sec) from nozzles  19   a,    20   a,  and  23   a,  the outer diameter D (cm) of the steel pipe P, and the adhesion efficiency n have the relationship expressed by Equation (2): q=W×nD×V/η. An example of ranges in which Equation (2) is satisfied are when the overall feed rate of lubricant q is set to 0.1-0.6 (ml/sec) and the speed of movement V is set to 4-12 (mm/sec). 
     As illustrated in  FIG. 1 , in order to shorten the cycle time and increase productivity, a plurality of spray guns  19  and  20  for spraying lubricant  9  at the pin  8   a  of the steel pipe P are preferably provided in the axial direction of the steel pipe P (two spray guns in the illustrated example). This permits the speed of movement V of the spray guns  19  and  20  to be easily increased. 
     In contrast, the range over which lubricant  9  is sprayed on the box  8   b  of the steel pipe P is often so short that it can be covered by spraying with a single spray gun  23  which is moved in the axial direction of the steel pipe P. Therefore, when it is possible to perform adequate application with the sprayed pattern of a single spray gun  23 , a single spray gun  23  may be provided. Of course, when application is not adequate with the sprayed pattern of a single spray gun  23  or it is desired to increase productivity, a plurality of spray guns for spraying lubricant  9  at the box  8   b  of the steel pipe P can be arranged in a row in the axial direction of the steel pipe P. In such cases, as described in the below-described example, a plurality of spray guns are preferably arranged in axially different positions such that the sprayed streams slightly overlap with each other on the surface of the steel pipe in order to avoid the occurrence of non-coated portions between the streams. 
     At the point where application is ended such as the end point of the threads of the steel pipe or to the rear of the threads on the inner surface, it is desirable to perform application in a circumferential direction instead of along a helical line in order to prevent unnecessary application. Therefore, at this point, it is preferable to stop the movement of the spray guns  19 ,  20 , and  23  in the axial direction of the steel pipe and continue spraying for around 0.8-2.3 seconds (the time required for one rotation of the steel pipe P) before spraying is terminated. 
     The wet coating thickness of lubricant  9  on the pin  8   a  or the box  8   b  of a steel pipe P is preferably at least 6 μm and at most 8 μm in order to obtain good lubricating properties without oozing of the lubricant. 
     A lubricant applying apparatus  1  according to the present invention can form a coating of a lubricant  9  having a desired thickness, but it is preferable to satisfy the relationship given by the above-described Equation (2). 
     The controlling unit  7  enables the stability of discharge of lubricant  9  which is sprayed from the lubricant spraying unit  5  to be increased. The controlling unit  7  can be used to control all the movements including the movement of the main body of the applying apparatus, the movement of the nozzles in the axial and radial directions, the rotational speed of the steel pipe, the rotational speeds or other actions of pumps, and on an off of spraying. 
     A lubricant applying apparatus  1  according to the present invention is constituted as described above. Next, an example of a method of applying a lubricant  9  to a pin  8   a  on the end of a steel pipe P using this lubricant applying apparatus  1  will be explained. 
     First, a steel pipe P having a threaded portion in the form of a pin  8   a  on the end of the pipe is mounted on the turning rollers  2   a  and  2   b,  and the steel pipe P is rotated in the direction of the arrows in  FIG. 1  by rotatingly driving the turning rollers  2   a  and  2   b  in the direction shown by the arrow in  FIG. 1 . 
     A highly viscous lubricant  9  (the above-described green dope having a biodegradability (BOD) of at least 20% after 28 days in sea water) which has been diluted with a volatile solvent to adjust its viscosity so as to be sprayable (e.g., CWSD EVS manufactured by Diado Chemical Industries, Co., Ltd.) is placed in the tank  10  of the lubricant circulating system  3 . The lubricant  9  in the tank  10  is then stirred by the stirring mechanism  10   a.    
     By setting the cock of the three-way valve  13  so as to allow circulation and starting the operation of the pump  12 , the lubricant  9  is circulated through the lubricant circulating system  3 . 
     Subsequently the solenoid valve  14  is set so as to select application of lubricant  9  to the pin  8   a,  and the first metering pump  4   a  for metered feeding to the first lubricant spraying unit  5  for applying lubricant  9  to the pin  8   a  is started. Lubricant  9  is thereby supplied to the first metering pump  4   a.    
     The first metering pump  4   a  performs metered feeding of lubricant  9  to the spray guns  19  and  20  through the lubricant feed passages  15   a  and  16   a.  At the same time, air for atomizing is fed to spray guns  19  and  20  through air feed passages  17   a  and  18   a  by an unillustrated system for feeding air for atomizing. The lubricant  9  and the atomizing air fed to the spray guns  19  and  20  are mixed together in the vicinity of the nozzles  19   a  and  20   a  at the tips of the spray guns  19  and  20 , and the lubricant  9  which is atomized by mixing with the atomizing air was sprayed towards the pin  8   a  of the steel pipe P through nozzles  19   a  and  20   a.    
     Simultaneous with the start of this spraying, the first spray gun support unit  24  is started, and the spray guns  19  and  20  which are disposed at predetermined angles with respect to the pin  8   a  are moved in the axial direction of the steel pipe P at a predetermined speed V (V≦m×n×L) and are moved at a predetermined speed in the radial direction of the steel pipe P. 
     The rotational speed of the steel pipe P by the steel pipe support unit  2  and the speed of axial movement of the spray guns  19  and  20  by the first spray gun support unit  24  are preferably controlled by the controlling unit  7 . 
     As a result, the lubricant  9  can be sprayed towards the pin  8   a  of the steel pipe P which is supported while rotating about its central axis. 
     As described above, with an apparatus and a method for applying lubricant to the threaded portions  8   a  and  8   b  of a steel pipe P according to the present invention, the coating thickness of lubricant  9  on the pin  8   a  of a steel pipe P can be controlled not only so that there is no oozing but so that good lubricating properties are obtained. 
     Specifically, with an apparatus and method for applying lubricant to the threaded portions  8   a  and  8   b  of a steel pipe P according to the present invention, by 
     (i) previously adjusting the viscosity of a highly viscous lubricant so as to be suitable for spraying by diluting with a volatile solvent or by heating, 
     (ii) circulating the lubricant  9  having its viscosity previously adjusted so as to be sprayable through a lubricant circulation system  3 , 
     (iii) stirring the lubricant  9  housed in a tank  10  with a stirring mechanism  10   a,    
     (iv) feeding lubricant  9  to spray guns  19  and  20  using a first metering pump  4   a  which has its discharge rate controlled by a servo motor  4   c,    
     (v) performing fine control of the speed of movement of the spray guns  19  and  20  using the first spray gun support unit  24  having servo motors  24   b  and  24   d  as drive sources, 
     (vi) optimally setting the spraying angles of the spray guns  19  and  20 , and 
     (vii) using the controlling unit  7  to performed high precision control of the rotational speed of the steel pipe P by the pipe support unit  2  and the speed of movement of the spray guns  19  and  20  by the spray guns support unit  6  so that the speed of movement V (mm/min) of the spray guns  19  and  20  in the axial direction by the spray gun support unit  6  satisfies Equation (1): V≦m×n×L and so as to be in the range of 15-25 mm/min, 
     the coating thickness of the lubricant  9  on the pin  8   a  of the steel pipe P can be controlled to be in the range of 6-8 μm in which not only is there no oozing of lubricant but good lubricating properties are obtained. 
     In the above explanation, an example was given of applying lubricant  9  to a pin  8   a  on the end of a steel pipe P. When applying lubricant  9  to a box  8   b  of a steel pipe P, the only difference is that the application of lubricant  9  to the box  8   b  is selected by switching the solenoid valve  14 , and other conditions are exactly the same. Therefore, an explanation of applying lubricant  9  to the box  8   b  of the steel pipe P will be omitted. 
     A lubricant applying apparatus according to the present invention can be designed so as to enable simultaneous application of a lubricant to the inner and outer surfaces of an end of a steel pipe. Therefore, it is possible to simultaneously apply a lubricant to a pin on the outer surface of an end of a steel pipe and a recess portion on the inner surface of that end of the steel pipe. 
     In this manner, with a lubricant applying apparatus  1  according to the present invention, a green dope which is a highly viscous lubricant can for the first time be thinly and uniformly applied with a predetermined coating weight and specifically with a low thickness of around 1/10 of the conventional thickness to the surface of a pin  8   a  or a box  8   b  of a steel pipe P and particularly to the surface of a pin  8   a  which is typically formed on the end of a long steel pipe P and which is difficult to coat. 
     In a lubricant applying apparatus  1  according to the present invention for applying lubricant to threaded portions  8   a  and  8   b  of a steel pipe P, if each of the feed rate of lubricant  9  by the first metering pump  4   a  and the feed rate of lubricant  9  by the second metering pump  4   b,  the rate of circulation of lubricant  9  by pump  12 , the distance of the nozzles  19   a  and  20   a  from the pin  8   a,  the distance of nozzle  23  from the box  8   b,  and the angles of the spray guns  19 ,  20 , and  23  at the time of spraying are maintained constant at previously determined values, lubricant  9  can be applied to a desired thickness to the pin  8   a  or the box  8   b  of the steel pipe P regardless of the outer diameter of the steel pipe P by using the controlling unit  7  so as to control the rotational speed of the steel pipe P by the steel pipe support unit  2  and the speed of movement of spray guns  19  and  20  by the first spray gun support unit  24  or the speed of movement of spray gun  23  by the second spray gun support unit  25 . 
     EXAMPLE 1 
     Using the lubricant applying apparatus  1  according to the present invention shown in  FIG. 1 , a highly viscous lubricant  9  having its viscosity adjusted by dilution (CWSD EVS manufactured by Daido Chemical Industry Co., Ltd.) was applied to the pin  8   a  formed on an end of a total of 17 steel pipes  8  including one steel pipe with an outer diameter of 2.375 inches (60.3 mm), three steel pipes having an outer diameter of 2.875 inches (73.0 mm), three steel pipes having an outer diameter of 3.5 inches (88.9 mm), three steel pipes having an outer diameter of 4 inches (101.6 mm), three steel pipes having an outer diameter of 4.5 inches (114.3 mm), one steel pipe having an outer diameter of 5 inches (127.0 mm), one steel pipe having an outer diameter of 5.5 inches (139.7 mm), one steel pipe having an outer diameter of 6.625 inches (168.3 mm), and one steel pipe having an outer diameter of 7 inches (177.8 mm). The thread shape of the pin of each of these steel pipes are the same as that shown in  FIG. 2 . 
     The spray guns  19  and  20  used to apply the lubricant to the pin had their nozzles oriented perpendicular to the surface of the steel pipe (thread crest) as shown in  FIG. 1 . Thus, the nozzles of the two spray guns had the same spraying angles as shown in  FIG. 3(   a ) instead of having differently tilted angles as shown in  FIG. 3(   b ). Thus, use of two spray guns which are spaced axially was to increase the efficiency of application. In this case, the length L of the major axis of the sprayed pattern at the pin  8   a  of the lubricant  9  which was sprayed from the spray guns  19  and  20  in a conical shape was 20 mm. In order to prevent the formation of intermittently uncoated portions in the axial direction of the steel pipe P between the helical coating, the spacing of the spray guns  19  and  20  in the axial direction of the steel pipe P was set to 17 mm corresponding to an overlap of  15 % of the sprayed axial length L (30% on both sides). If the diameter of the turning rollers  2   a  and  2   b  is H (mm) and the rotational speed of the turning rollers  2   a  and  2   b  is R (rpm), the time T′ (sec) required for one rotation of the steel pipe P becomes OD/(H×R/60). Therefore, if the coated length is L (mm) and the speed of movement of the spray guns  19  and  20  is P (mm/rev), the coating time T (sec) becomes T=T′×(L/P+2) since movement of the spray guns is stopped for one rotation at the start and at the stop of spraying to prevent uneven application. 
     In this coating process, the discharge rate V from the first metering pump  4   a  was maintained constant at 8.65 g/min and the rotational speed of the first metering pump  4   a  was maintained constant at 25.44 rpm regardless of the outer diameter of the steel pipe P. Therefore, the applied amount is given by T/60×V. 
     The tolerance of application (Min, Max, and Median expressed in grams) was the tolerance of the overall coating weight which was obtained by actual measurement. 
     The results are compiled in Table 1. In Table 1, WT indicates the wall thickness of the pipe, T/R indicates the turning roller, and the pump indicates the first metering pump  4   a  (which was a rotary plunger pump having variable rotational speed). Pump constant indicates the volume discharged from the pump during one revolution. Pump constant and number of pump revolutions are the values in the first metering pump  4   a.    
     
       
         
           
               
               
               
               
               
               
               
             
               
                   
                 TABLE 1 
               
             
            
               
                   
                   
               
               
                   
                 Rota- 
                   
                 Discharge 
                   
                 Rota- 
                   
               
            
           
           
               
               
               
               
               
               
               
               
               
               
            
               
                   
                 Wall 
                   
                 Di- 
                 tional 
                   
                 rate of 
                   
                 tional 
                   
               
            
           
           
               
               
               
               
               
               
               
               
               
               
               
               
               
            
               
                 Outer 
                 thickness WT 
                 Tolerance of 
                 Nozzle 
                 Thread 
                 ameter 
                 speed of 
                   
                 Coating 
                 metering 
                 Pump 
                 speed of 
                 Coating 
               
               
                 diameter 
                 (mm) 
                 application 
                 pitch 
                 length 
                 of T/R 
                 T/R 
                 T′ 
                 time 
                 pump 
                 constant 
                 pump 
                 weight 
               
            
           
           
               
               
               
               
               
               
               
               
               
               
               
               
               
               
               
               
               
            
               
                 in 
                 mm 
                 Min 
                 Max 
                 Min 
                 Max 
                 Median 
                 mm/rev 
                 mm 
                 mm 
                 rpm 
                 sec 
                 sec 
                 g/min 
                 cc/rev 
                 rpm 
                 g 
               
               
                   
               
            
           
           
               
               
               
               
               
               
               
               
               
               
               
               
               
               
               
               
               
            
               
                 2.375 
                 60.3 
                 6.45 
                 8.53 
                 0.9 
                 1.2 
                 1.05 
                 17 
                 73.44 
                 190 
                 16.8 
                 1.13 
                 7.17 
                 8.65 
                 0.34 
                 25.44 
                 1.03 
               
               
                 2.875 
                 73.0 
                 5.51 
                 5.51 
                 1.1 
                 1.6 
                 1.35 
                 17 
                 63.97 
                 190 
                 16.8 
                 1.37 
                 7.91 
                 8.65 
                 0.34 
                 25.44 
                 1.14 
               
               
                 2.875 
                 73.0 
                 7.01 
                 10.29 
                 1.2 
                 1.7 
                 1.45 
                 17 
                 80.77 
                 190 
                 16.8 
                 1.37 
                 9.27 
                 8.65 
                 0.34 
                 25.44 
                 1.34 
               
               
                 2.875 
                 73.0 
                 11.18 
                 11.18 
                 1.3 
                 1.8 
                 1.55 
                 17 
                 90.37 
                 190 
                 16.8 
                 1.37 
                 10.04 
                 8.65 
                 0.34 
                 25.44 
                 1.45 
               
               
                 3.5 
                 88.9 
                 4.32 
                 7.34 
                 1.3 
                 1.8 
                 1.55 
                 17 
                 77.02 
                 190 
                 16.8 
                 1.67 
                 10.91 
                 8.65 
                 0.34 
                 25.44 
                 1.57 
               
               
                 3.5 
                 88.9 
                 9.53 
                 11.4 
                 1.5 
                 2.0 
                 1.75 
                 17 
                 97.02 
                 190 
                 16.8 
                 1.67 
                 12.88 
                 8.65 
                 0.34 
                 25.44 
                 1.86 
               
               
                 3.5 
                 88.9 
                 12.09 
                 14.61 
                 1.6 
                 2.1 
                 1.85 
                 17 
                 108.22 
                 190 
                 16.8 
                 1.67 
                 13.98 
                 8.65 
                 0.34 
                 25.44 
                 2.02 
               
               
                 4 
                 101.6 
                 4.83 
                 8.38 
                 1.6 
                 2.1 
                 1.85 
                 17 
                 81.83 
                 190 
                 16.8 
                 1.91 
                 13.01 
                 8.65 
                 0.34 
                 25.44 
                 1.88 
               
               
                 4 
                 101.6 
                 9.65 
                 10.92 
                 1.8 
                 2.5 
                 2.15 
                 17 
                 102.65 
                 190 
                 16.8 
                 1.91 
                 15.35 
                 8.65 
                 0.34 
                 25.44 
                 2.21 
               
               
                 4 
                 101.6 
                 12.7 
                 15.49 
                 1.9 
                 2.6 
                 2.25 
                 17 
                 115.45 
                 190 
                 16.8 
                 1.91 
                 16.79 
                 8.65 
                 0.34 
                 25.44 
                 2.42 
               
               
                 4.5 
                 114.3 
                 5.69 
                 8.56 
                 1.7 
                 2.2 
                 1.95 
                 17 
                 81.83 
                 190 
                 16.8 
                 2.15 
                 14.64 
                 8.65 
                 0.34 
                 25.44 
                 2.11 
               
               
                 4.5 
                 114.3 
                 9.65 
                 10.92 
                 2.0 
                 2.7 
                 2.35 
                 17 
                 102.65 
                 190 
                 16.8 
                 2.15 
                 17.27 
                 8.65 
                 0.34 
                 25.44 
                 2.49 
               
               
                 4.5 
                 114.3 
                 12.7 
                 14.22 
                 2.2 
                 3.1 
                 2.65 
                 17 
                 115.45 
                 190 
                 16.8 
                 2.15 
                 18.89 
                 8.65 
                 0.34 
                 25.44 
                 2.72 
               
               
                 5 
                 127.0 
                 6.43 
                 12.7 
                 2.7 
                 3.6 
                 3.15 
                 17 
                 106.45 
                 190 
                 16.8 
                 2.39 
                 19.72 
                 8.65 
                 0.34 
                 25.44 
                 2.84 
               
               
                 5.5 
                 139.7 
                 6.2 
                 14.27 
                 3.0 
                 4.2 
                 3.6 
                 17 
                 111.31 
                 190 
                 16.8 
                 2.63 
                 22.45 
                 8.65 
                 0.34 
                 25.44 
                 3.24 
               
               
                 6.625 
                 168.3 
                 7.32 
                 14.27 
                 3.9 
                 5.4 
                 4.65 
                 17 
                 112.45 
                 190 
                 16.8 
                 3.16 
                 27.25 
                 8.65 
                 0.34 
                 25.44 
                 3.93 
               
               
                 7 
                 177.8 
                 8.05 
                 15.88 
                 4.3 
                 5.7 
                 5.0 
                 17 
                 121.31 
                 190 
                 16.8 
                 3.34 
                 30.53 
                 8.65 
                 0.34 
                 25.44 
                 4.40 
               
               
                   
               
               
                 T′: Time required for one rotation of the pipe 
               
            
           
         
       
     
     As shown in Table 1, in a lubricant applying apparatus  1  according to the present invention, if the feed rate of lubricant  9  by the first metering pump  4   a,  the rate of circulation of lubricant  9  by pump  12 , the distance of nozzles  19   a  and  20   a  from the pin  8   a,  and the angles of the spray guns  19  and  20  at the time of spraying are all maintained constant at previously determined values, it can be seen that a lubricant  9  can be applied to the pin  8   a  of the steel pipe P to a desired thickness which satisfies tolerances regardless of the outer diameter of a steel pipe by controlling by means of the controlling unit  7  only the rotational speed of the steel pipe P by the steel pipe support unit  2  and the speeds of movement of spray guns  19  and  20  by the first spray gun support unit  24 . 
     Fine adjustment of the coating thickness can be easily carried out by varying the rotational speed of the first metering pump  4   a  and varying the feed rate of the lubricant  9 . 
     In this manner, according to the present invention, a highly viscous lubricant can be thinly and uniformly applied with a predetermined coating weight to the surface of a pin or a box of a threaded joint for pipes and particularly to the surface of a pin which is typically formed on the end of a long steel pipe and which is difficult to coat. Specifically, the highly viscous lubricant can be uniformly applied to a thickness of around 1/10 of the conventional value.