Abstract:
A solder-on connector for a coaxial cable includes a body having a bore for receiving the outer conductor of the cable, a center pin for connection with the center conductor of the cable, an insulator disposed within the bore of the body for supporting the center pin, and a nut or similar fastener for securing the connector to a mating connector. The insulator extends rearwardly within the body to abut the both the inner wall of the body and the inserted end of the outer conductor of the cable. The rearmost portion of the insulator serves as a solder dam to prevent excess solder from flowing into the bore of the body beyond the end of the outer conductor of the cable. The rearmost end of the body includes an enlarged diameter region for receiving a portion of the cable jacket. An inwardly-directed annular shoulder formed upon such enlarged diameter region captivates melted portions of the cable jacket when the outer conductor is soldered to the body.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to connectors for terminating the ends of coaxial cables of the general type used in the telecommunications industry, and more specifically, to an improved connector that can easily be soldered onto the end of such a coaxial cable. 
     2. Description of the Related Art 
     Coaxial cable is widely used in the telecommunications industry to transport radio frequency signals. Such coaxial cable typically includes a center conductor made of copper for transmitting signals. The center conductor is surrounded by a dielectric material which, in turn, is surrounded by a semi-rigid, metallic outer conductor. The outer conductor may be relatively smooth, or it may be corrugated to enhance or ease bending of the coaxial cable. Typically, the outer conductor is covered by an insulative jacket to protect the outer conductor and to seal out moisture. 
     It is necessary to electrically and mechanically couple the ends of such coaxial cables to equipment ports or other cables in a system, and end connectors for serving such purpose are known. Examples of such coaxial cable connectors include U.S. Pat. No. 4,854,893 to Morris, and U.S. Pat. No. 4,923,412 to Morris; these patents disclose the use of a ferrule which is mechanically compressed against the outer conductor to clamp the coaxial cable within the connector. These patents also disclose the use of a collet to mechanically seize the center conductor of the coaxial cable and to thereby establish an electrical coupling between the center conductor and the center pin of the connector. Other examples of coaxial cable connectors of this general type include U.S. Pat. No. 6,019,636 to Langham, U.S. Pat. No. 5,352,134 to Jacobsen, et al., U.S. Pat. No. 5,651,698 to Locati, et al.; and U.S. Pat. No. 6,183,298 to Henningsen. 
     Despite efforts to seal such connectors from the elements, moisture sometimes penetrates into such connectors and corrodes the electro/mechanical contact between the center pin of the connector and the center conductor of the cable, resulting in a loss of signal strength or other signal degradation. Likewise, corrosion can form between the mechanism that clamps the connector to the outer conductor of the coaxial cable, thereby compromising the shielding of the desired signal from interference, and also allowing the signal being conducted to leak out of the cable. 
     Efforts have been made to avoid such problems by providing connectors that can be soldered onto the prepared end of a coaxial cable. For example, U.S. Pat. No. 5,802,710 to Bufanda, et al. describes a coaxial cable assembly which includes an end connector having a center pin that is soldered onto the end of the center conductor. An insulative disc is inserted over the exposed end of the cable, around the center conductor, before the center pin is soldered onto the exposed end of the center conductor. Bufanda, et al. explain that such insulative disc acts as a “solder gauge” by spacing the center pin of the connector at the proper axial distance from the exposed end of the coaxial cable. Pre-formed solder is then applied over the exposed outer conductor, and a body member is inserted over the exposed end of the cable. The body member includes a further insulator having a center hole formed therein for allowing the center pin to extend therethrough, while providing mechanical support to the center pin. A fastening nut is rotatably secured to the body member for fastening the connector to a mating connector. After the body member is slid over the outer conductor, the connector is heated to melt the pre-formed solder to establish a mechanical and electrical connection between the body member and the outer conductor of the coaxial cable. Bufanda et al. explain that the aforementioned insulative disc causes solder pooling to occur between the outer conductor and the body member at the location of the insulative disc to create a circumferential seal therebetween. 
     The connector described by Bufanda et al. requires the use of both an insulative disc and a second insulator to support the center pin within the body member. The need for two such insulators increases the cost of such connector. Moreover, the connector described by Bufanda et al. relies entirely upon the solder connection between the outer conductor of the coaxial cable and the body member to maintain mechanical coupling between the connector and the coaxial cable. Mechanical stress applied to such solder joint, due for example to pulling forces and/or bending forces at the connector/cable junction, can compromise the mechanical and electrical coupling between the outer conductor of the coaxial cable and the body member, and can degrade the moisture seal formed therebetween. In addition, the single mechanical support, formed at the solder joint between the outer conductor of the cable and the body member, tends to act as a fulcrum or pivot point; movement of the coaxial cable behind the connector is thereby transmitted, via the center conductor, to the center pin of the connector, resulting in movement at the connector interface. Such movement at the connector interface causes electrical performance instability and intermodulation distortion instability. 
     Accordingly, it is an object of the present invention to provide a coaxial cable connector that can be easily and conveniently soldered onto the end of a coaxial cable. 
     It is another object of the present invention to provide such a coaxial cable connector which allows the user to solder the body of the connector to the outer conductor of the coaxial cable, and which optionally allows a user to solder the center pin of the connector to the center conductor of the coaxial cable. 
     Still another object of the present invention is to provide such a coaxial cable connector which prevents excess solder from flowing into the body beyond the end of the outer conductor of the coaxial cable. 
     Yet another object of the present invention is to provide such a coaxial cable connector with improved pull-off strength. 
     A further object of the present invention is to provide such a coaxial cable connector that captures the cable jacket to prevent the possibility of it shrinking, or pulling back, thereby maintaining moisture seal integrity. 
     A still further object of the present invention is to provide such a coaxial cable connector with enhanced electrical and intermodulation distortion stability. 
     Another object of the present invention is to provide additional mechanical support between the coaxial cable and the connector to eliminate the above-described fulcrum/pivot action of the solder joint formed between the outer conductor of the cable and the body of the connector. 
     A still further object of the present invention is to provide such a coaxial cable connector with an improved seal between the body of the connector and the coaxial cable jacket to reduce moisture penetration and related corrosion-induced reliability problems. 
     A yet further object of the present invention is to provide such a coaxial cable connector that is less subject to mechanically induced stress and strain due to bending of the coaxial cable near the rear of the connector. 
     These and other objects of the present invention will become more apparent to those skilled in the art as the description of the present invention proceeds. 
     SUMMARY OF THE INVENTION 
     Briefly described, and in accordance with a preferred embodiment thereof, the present invention relates to a solder-on connector for a coaxial cable and including a body member having a first end with an internal bore formed therein to provide a generally cylindrical cavity for receiving an exposed end of a coaxial cable, and a coupler secured to the second opposing end of the body member to removably fasten the connector to a mating coaxial connector; this coupler could take the form of a rotatable internally-threaded coupling nut, a rotatable externally-threaded member, a bayonet-style rotatable coupler, or the like. Alternatively, the coupler could be fixedly-secured to the second end of the body member, in the form of external threads formed upon the second end of the body member for mating with a rotatable nut on a mating component, or bayonet-style“ears” formed upon the second end of the body member for mating with a rotatable connector of a mating component. On the other hand, the coupler could simply be a flange formed upon the second end of the body member, the flange extending generally perpendicular to the body member and having mounting holes formed around the outer periphery thereof for receiving mounting screws or bolts used to secure such flange to a similar flange of a mating component. As used herein, the terms “coupler” and “fastener” could include all of such coupling mechanisms and their equivalents. 
     The solder-on connector of the present invention also includes an insulator that is received within the generally cylindrical cavity of the body member. This insulator extends between first and second ends relative to the longitudinal axis of the body member. The first end of the insulator has a generally cylindrical outer wall having an outer diameter generally commensurate with the internal diameter of the bore formed in the first end of the body member. The first end of the insulator is adapted to abut an exposed edge of the outer conductor of a coaxial cable inserted within the first end of the body member. The second end of the insulator has a central aperture extending therethrough that is generally coaxial with the longitudinal axis of the body member. The solder-on connector further includes a pin having a first end for engaging the center conductor of the coaxial cable, and having an opposing second end which extends outwardly through the aperture formed in the second end of the insulator. The pin is, at least in part, supported by the aperture formed in the second end of the insulator, thereby centering the pin with the longitudinal axis of the body member. 
     Preferably, the first end of the pin has a bore formed therein for receiving an exposed end of the center conductor of the coaxial cable. In the preferred embodiment of the invention, a solder joint is formed between the first end of the pin and the exposed end of the center conductor. 
     It was mentioned above that among the objects of the present invention are to provide such a coaxial cable connector with improved pull-off strength, enhanced electrical performance instability and intermodulation distortion stability, an improved seal between the body of the connector and the coaxial cable jacket, and reduced susceptibility to mechanically induced stress and strain due to bending of the coaxial cable near the first end of the connector. To such ends, the present invention preferably includes an outermost region located at the first-end opening of the body member, the outermost region having an internal diameter that exceeds the inner diameter of the aforementioned bore formed in the first end of the body member, and which exceeds the outer diameter of the outer protective jacket of the coaxial cable. Consequently, this outermost region of the body member is adapted to receive a portion of the protective jacket of the coaxial cable. Preferably, the inner diameter of this outermost region is joined with the generally cylindrical cavity of the body member by an inwardly tapered wall. Also in the preferred embodiment of the present invention, the outermost region of the body member includes an inwardly directed flange proximate the first end of the body member. 
     The protective jacket of the coaxial cable is typically made of a thermoplastic material having a characteristic reflow temperature at which it deforms. When the body member of the connector is heated to solder the body member to the outer conductor of the coaxial cable, the portion of the protective jacket received within the outermost region of the body member “melts”; at this time, the inwardly directed flange of the outermost region of the body member serves to capture melted portions of the protective jacket of the coaxial cable when the same is heated to its characteristic reflow temperature. When the connector cools, the melted portions of the protective jacket solidify, forming a strong supportive joint between the protective jacket and the outermost region of the body member. Those skilled in the art will appreciate that the aspect of applicant&#39;s invention relating to the capture of melted portions of the protective jacket within the outermost region of the body member can be used to advantage whether or not the center conductor of the coaxial cable is actually soldered to the center pin of the solder-on connector. 
     The insulator used to support the pin within the body member can assume different shapes. For example, the insulator can be generally shaped like a cup, with the “mouth” of the cup facing the exposed end of the coaxial cable, and the centering hole being formed in the “base” of the cup. In this case, the generally circular outer wall of the cup-shaped insulator is spaced apart from, and surrounds, the first end of the pin. Alternatively, the insulator can be a solid, or partially-solid, cylinder, or it may be generally conical, with the “base” of the cone facing the exposed end of the coaxial cable, and the peaked end of the cone being directed toward the second end of the body member for supporting the pin. 
     Regardless of the shape of the insulator, if the pin of the connector is to be soldered onto the center conductor of the coaxial cable, then the insulator preferably extends along the longitudinal axis of the body member for a length that is greater than one-half of the internal diameter of the generally cylindrical cavity formed in the first end of the body member. Thus, if the insulator is cup-shaped, then the height (or length) of the cup is preferably at least one-half of its maximum diameter. It is preferred that the centering hole formed in the second end of the insulator be commensurate with the diameter of the pin to result in a press fit between the pin and the insulator. As the insulator is press fit over the pin, the first end of the insulator is preferably advanced at least as far as the first end of the pin along the longitudinal axis of the body member. 
     Another aspect of the present invention relates to a method of forming a solder-on end connector, of the general type described above, upon an exposed end of a coaxial cable, wherein both the center conductor of the coaxial cable and the outer conductor of the coaxial cable are joined by solder to the end connector. To practice such method, a pin is provided having first and second ends, the first end of the pin having a central bore. The exposed end of the center conductor of the coaxial cable is inserted into the central bore of the first end of the pin. The first end of the pin is soldered to the center conductor of the coaxial cable. An insulator is provided having a first end that includes a generally cylindrical outer wall having an outer diameter; the second opposing end of the insulator has a central aperture. The insulator is inserted over the second end of the pin, via the center aperture, until the first end of the insulator abuts an exposed edge of the outer conductor of the coaxial cable. A body member is provided having first and second opposing ends, the first end of the body member including a first-end opening leading into a generally cylindrical cavity having an internal diameter commensurate with the diameter of the outer conductor of the coaxial cable. The first end of the body member is inserted over the exposed end of the coaxial cable, over the second end of the pin, and over the insulator. Solder is applied between the outer conductor of the coaxial cable and the generally cylindrical cavity of the body member. The solder is heated to couple the outer conductor of the coaxial cable with the body member. 
     Preferably, the step of providing the body member includes the step of forming an outermost region within the first end of the body member, wherein the internal diameter of such outermost region exceeds the inner diameter of the generally cylindrical cavity. In this case, the step of sliding the first end of the body member over the exposed end of the coaxial cable includes the step of sliding the outermost region of the body member over the protective jacket of the coaxial cable to allow a portion of the protective jacket to enter such outermost region. Assuming that the protective jacket of the coaxial cable is made of a thermoplastic material having a characteristic reflow temperature at which it deforms, then the aforementioned step of heating the solder to couple the outer conductor of the coaxial cable with the body member includes the further step of heating the protective jacket to its characteristic reflow temperature for melting portions of the protective jacket within the outermost region of the first end of the body member. To further ensure a secure connection between the protective jacket and the outermost region of the body member, the step of forming such outermost region preferably includes the step of forming an inwardly directed flange within such outermost region proximate the first end of the body member for capturing melted portions of the protective jacket of the coaxial cable when the same is heated to its characteristic reflow temperature during the soldering step. Those skilled in the art will appreciate that the central pin of the connector need not necessarily be soldered to the center conductor of the coaxial cable, in which case, the central pin, surrounding insulator, and body member can be pre-assembled. 
     In practicing the above-described method, the step of applying solder between the outer conductor of the coaxial cable and the body member can be performed in a number of different ways. For example, the step of applying such solder may include the step of applying solder paste within the body member before sliding the body member over the pin, insulator, and coaxial cable. Likewise, the step of applying such solder may include the step of applying solder paste onto the outer conductor of the coaxial cable before sliding the body member over the pin, insulator, and coaxial cable. Alternatively, such solder might be provided by applying pre-formed solder onto the outer conductor of the coaxial cable before sliding the body member over the pin, insulator, and coaxial cable. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a sectional drawing of a connector and attached coaxial cable in accordance with the present invention. 
     FIG. 2 is an enlarged detailed view of a portion of the connector shown in FIG. 1 illustrating the entrapment of a melted portion of the cable jacket within an outermost region of the connector body. 
     FIG. 3 is a perspective view illustrating the exposed end of a coaxial cable having a corrugated outer conductor and a protective outer thermoplastic jacket. 
     FIG. 4 is a perspective view corresponding to FIG. 3 after a center pin has been secured over the center conductor of the coaxial cable. 
     FIG. 5 is a perspective view corresponding to FIGS. 3 and 4 after a cup-shaped insulator has been press fit over the center pin shown in FIG.  4 . 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In FIG. 1, a coaxial solder-on connector  6  is shown along with a coaxial cable  8  in accordance with the present invention. Coaxial cable  8  includes a center conductor  30  surrounded by dielectric insulator material  28 . Coaxial cable  8  also includes a semi-rigid metallic outer conductor  26  that surrounds dielectric material  28 ; in FIG. 1, such outer conductor  26  is illustrated as being corrugated to facilitate bending and/or flexing of the coaxial cable. Those skilled in the art, however, will recognize that such outer conductor may also be of relatively smooth, uniform diameter. The outer conductor  26  is encased in a protective jacket  24 , typically made of a thermoplastic material. 
     Referring briefly to FIG. 3, the end of coaxial cable  8  is shown after preparation for termination by connector  6 . As shown in FIG. 3, protective jacket  24  is removed from the end of the coaxial cable to expose an end portion of the underlying outer conductor  26 . Likewise, a portion of outer conductor  26  and underlying dielectric material  28  are removed from the end of the coaxial cable to expose a stub of center conductor  30 . The edge of outer conductor  26  is designated in FIG. 3 by reference numeral  29 . 
     Returning to FIG. 1, connector  6  includes a body member  12  that extends between a first end  13  and a second opposing end  15  along a longitudinal axis indicated by dashed lines  33 . Body member  12  is metallic and electrically conductive. Connector  6  also includes a fastener, shown in the form of a coupling nut  14 , rotatably coupled to, and surrounding, second end  15  of body member  12 . Coupling nut  14  is secured to body member  12  by retaining ring  16 . A gasket  18  is inserted inside coupling nut  14 , and surrounding second end  15  of body member  12 , to form a moisture seal between such components. Coupling nut  14  is also preferably metallic and electrically conductive. Coupling nut  14  has internal threads formed upon inner bore  17  and is adapted to removably engage a mating externally-threaded connector, for example, a threaded connector extending from an equipment box to which the coaxial cable  8  is to be connected. The outer periphery of coupling nut  14  is preferably hexagonal in shape to allow a standard hex installation wrench to be used to tighten coupling nut  14  onto a mating connector. It should be noted, however, that the fastener corresponding to coupling nut  14  could actually be externally threaded for being received within an internally-threaded mating connector, as well as a bayonet-style rotatable coupler, or the like. Alternatively, coupling nut  14  could be replaced by external threads, or bayonet-style “ears”, fixedly-secured to second end  15  of body member  12 , in order to mate with another component. 
     Body member  12  has a bore or opening  19  (see FIG. 2) formed in first end  13  thereof to form a generally cylindrical cavity. The internal diameter of this generally cylindrical cavity is slightly larger than, but commensurate with, the outer diameter of outer conductor  26  of coaxial cable  8  to receive the exposed portion of outer conductor  26  shown in FIG.  3 . Solder material, shown in FIG. 1 by reference numeral  27 , is used to secure, and electrically couple, outer conductor  26  of cable  8  to the inner wall of body member  12 . As shown in FIG. 1, the internal diameter of the generally cylindrical cavity decreases slightly to create a step at the point designated by reference numeral  21 . Step  21  serves as a stop to limit the extent to which outer conductor  26  of coaxial cable  8  can be advanced into the generally cylindrical cavity of body member  12 . 
     As shown in FIG. 1, the reduced-diameter region of the generally cylindrical cavity continues from step  21  toward second end  15  of body member  12  until it reaches a second step  31 . Disposed within this reduced-diameter region of body member  12  is an insulator  22  made of dielectric material. In the embodiment shown in FIG. 1, this insulator is shaped generally like a cup that has been turned on its side. The “rim” of the cup corresponds to a first end  34  of the insulator, and the “base” of the cup corresponds to an opposing second end  36  of the insulator. First end  34  of insulator  22  has a generally cylindrical outer wall  38 , the outer diameter of which is generally commensurate with the internal diameter of the reduced-diameter region of the generally cylindrical cavity of body member  12 ; indeed, in the cup-shaped insulator embodiment shown in FIGS. 1 and 5, the entire outer wall of cup-shaped insulator  22  has the same outer diameter. The distance from first end  34  of insulator  22  to the second end  36  of insulator  22  (i.e., the “height,” or length, of the cup, in this embodiment) preferably corresponds to the distance between first step  21  and second step  31  within the reduced-diameter region of the generally cylindrical cavity of body member  12 . In this manner, insulator  22  just fits within such reduced diameter region, with first end  34  (the “rim”) of insulator  22  just abutting the exposed edge  29  of outer conductor  26  of inserted coaxial cable  8 . 
     Second end  36  of insulator  22  has an aperture  39  formed therein extending generally coaxial with longitudinal axis  33  of body member  12 . Connector  6  further includes a center pin  20  that includes a first end  40  for being electrically coupled with center conductor  30  of coaxial cable  8 . Preferably, first end  40  of center pin  20  has a bore  46  formed therein for receiving the bared end of center conductor  30  of coaxial cable  8 . Since insulator  22  is essentially hollow at its first end  34 , the generally cylindrical outer wall  38  of insulator  22  proximate first end  34  is spaced apart from first end  40  of center pin  20 . The second opposing end  42  of center pin  20  extends within the second end portion  15  of body member  12 . The second end portion  15  of body member  12  is generally tubular in configuration, has a smaller diameter than that of the generally cylindrical cavity of body member  12 , and opens into the generally cylindrical cavity. A central portion  44  of center pin  20  passes through, and is supported by, aperture  39  of insulator  22 . Preferably, central portion  44  of center pin  20  forms a press fit with insulator  22 , wherein center pin  20  is supported within body member  12  generally coaxial with longitudinal axis  33 . 
     Referring to FIGS. 1 and 2, first end  13  of body member  12  includes an expanded outermost region  48  having an internal diameter that exceeds the inner diameter of the generally cylindrical cavity (bore  19 ) for allowing the end portion of protective jacket  24  of coaxial cable  8  to enter outermost region  48 . As shown best in FIG. 2 outermost region  48  is joined with the generally cylindrical cavity defined by bore  19  via inwardly tapered wall  50 . Protective jacket  24  of coaxial cable  8  is preferably made of a thermoplastic material that has a characteristic reflow temperature at which it deforms. During the process of soldering body member  12  to outer conductor  26  (described in greater detail below), heat applied to body member  12  serves to melt and deform the end portion of protective jacket  24 , causing it to “ball-up” and fill outermost region  48  of body member  12 . In FIG. 2, this “balled-up” portion of protective jacket  24  is designated by reference numeral  52 . To further ensure that balled-up portion  52  is retained within outermost region  48  of body member  12 , an inwardly directed flange or annular shoulder  54  is preferably formed upon the inner wall of outermost region  48  proximate first end  13  of body member  12  to capture the balled-up portion  52  of protective jacket  24 . After the connector cools down following the soldering operation, a firm joint is established between protective jacket  24  and connector body  12 , resulting in improved pull-off strength as between connector  6  and coaxial cable  8 , enhanced electrical performance instability and intermodulation distortion stability of the connector, an improved moisture seal between body member  12  coaxial cable jacket  24 , and reduced susceptibility to mechanically induced stress and strain due to bending of coaxial cable  8  near first end  13  of body member  12 . 
     The insulator  22  described above in conjunction with FIGS. 1 and 5 was described as being “cup-shaped”. Those skilled in the art, however, will appreciate that insulator  22  could also be a solid cylinder. In this case, aperture  39  would still be formed to receive central portion  44  of center pin  20 . In addition, a further aperture would extend into first end  34  of insulator  22  of slightly larger diameter to accommodate first end  40  of center pin  20 . As an alternative, insulator  22  could be generally conically-shaped, with the base of its “cone” forming the first end  34  of insulator  22  abutting exposed edge  29  of outer conductor  26 , and with the truncated tip of its “cone” encircling and supporting center pin  20 . 
     It will be appreciated that insulator  22  serves multiple functions in the present invention. First, second end  36  of insulator  22  provides mechanical support for center pin  20 , supporting center pin  20  along the longitudinal axis  33  of connector  6  while insulating center pin  20  from body member  12 . In addition, first end  34  of insulator  22  abuts the exposed edge  29  of outer conductor  26  and functions as a “solder dam”, effectively preventing any molten solder that exists in the space between outer conductor  26  and body member  12  from flowing into body member  12  beyond the exposed edge  29  of outer conductor  26 . Any such molten solder that attempts to flow further contacts the relatively cool surface of insulator  22  and solidifies upon such contact. It is preferred that insulator  22  have at least a minimum “height” (as measured between first end  34  and second end  36  that is greater than one-half of the internal diameter of the generally cylindrical cavity of body member  12 . First end  34  of insulator  22  should extend as far, and preferably slightly further, along longitudinal axis  33  of connector  6  as does first end  40  of center pin  20  to help ensure that first end  34  of insulator  22  firmly abuts the exposed edge  20  of outer conductor  26 . 
     As mentioned above, the present invention also relates to a method of forming a solder-on end connector upon an exposed end of a coaxial cable. A preferred embodiment of such method will now be described in conjunction with FIGS. 1-5. First, coaxial cable  8  is prepared in the manner illustrated by FIG.  3 . Next, center pin  20  is provided having first end  40  with a central bore  46 , and having second end  42 . The exposed end of center conductor  30  of coaxial cable  8  is then inserted into central bore  46  of first end  40  of center pin  20 , in the manner illustrated in FIG.  4 . Preferably, heated solder is then applied to the joint formed between center conductor  30  and first end  40  of center pin  20  to form a soldered joint therebetween. In this regard, it may be important that the second end  42  of center pin  20  be spaced apart from exposed edge  29  of outer conductor  26  by a fixed distance; if so, a positioning jig, or spacing tool, can be used to space first end  40  of center pin  20  by a desired amount from the exposed face of dielectric material  28  before center pin  20  is soldered to the exposed stub of center conductor  30 . 
     Next, insulator  22  is press fit over center pin  20 , firmly engaging aperture  39  of insulator  22  over the central region  44  of center pin  20  until first end  34  of insulator  22  abuts exposed edge  29  of outer conductor  26  of coaxial cable  8 . First end  13  of body member  12  is then slid over center pin  20 , insulator  22 , and coaxial cable  8 , until second end  36  of insulator  22  rests against step  31  of the generally cylindrical cavity of body member  12 . Preferably, a portion of the protective jacket  24  is simultaneously inserted into outermost region  48  of body member  12 . Solder  27  is applied between outer conductor  26  of coaxial cable  8  and the inner wall defining the generally cylindrical cavity of body member  12 . Such solder might be in the form of a solder paste that is applied to the inner wall of body member  12  and/or solder paste applied to the outer conductor  26  of coaxial cable  8 . Alternatively, solder  27  might be in the form of a so-called “pre-form” inserted over outer conductor  26  just before the exposed end of coaxial cable  8  is inserted into connector  6 . Body member  12  is then heated to couple outer conductor  26  of coaxial cable  8  with body member  12 . First end  34  of insulator  22  prevents such solder from advancing into the generally cylindrical cavity of body member  12  beyond the exposed edge  29  of outer conductor  26 . Simultaneously, the portion of protective jacket  24  received within the outermost region  48  of body member  12  is heated to its reflow temperature, thereby deforming, and becoming firmly ensnared by hook  54 . 
     Those skilled in the art will now appreciate that the described coaxial cable connector can be easily and conveniently soldered onto the end of a coaxial cable. A user can solder the body of the connector to the outer conductor of the coaxial cable, and if desired, the user can also solder the center pin of the connector to the center conductor of the coaxial cable. The above-described insulator prevents excess solder from flowing into the connector body beyond the end of the outer conductor of the coaxial cable. Moreover, the deformation and entrapment of the end portion of the protective jacket within the connector provides improved pull-off strength, enhanced electrical performance instability and intermodulation distortion stability, additional mechanical support between the coaxial cable and the connector, reduced susceptibility to mechanically induced stress and strain due to bending of the coaxial cable near the rear of the connector, and enhanced moisture-sealing capabilities. 
     While the present invention has been described with respect to preferred embodiments thereof, such description is for illustrative purposes only, and is not to be construed as limiting the scope of the invention. Various modifications and changes may be made to the described embodiments by those skilled in the art without departing from the true spirit and scope of the invention as defined by the appended claims.