Rigidly securable water resistive electrical connector

An electrical connector assembly including a first electrical connector and a second electrical connector connected therein in an electrical engagement. Each of the first and second electrical connectors including outer protective housings which are tapered from the connecting point between the first and second electrical connectors to opposite ends of each of the electrical connectors. Each of the protective housings includes internal bores in which is seated an electrical unit supporting electrical terminals and associated contacts in wires connected thereto. The wires extend from the electrical units through openings at opposite ends of the first and second electrical connectors. A threaded sleeve is threadably engagable with outer threads of the first and second connectors such that the first and second connectors are rigidly secured to each other.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates generally to an electrical connector assembly and, 
more specifically, to an electrical connector assembly having first and 
second connectors each including design features for reliably securing the 
first connector to the second connector and for maintaining the integrity 
of the connection against moisture. 
2. Discussion of the Related Art 
Electrical devices, such as power tools and the like, which run on 
alternating current and are portable in order to expand the range of use 
of the device include an electrical power cord for delivering power to the 
device. The power cord will include a connector electrically attached to 
the cord opposite to the device for connecting the cord to an alternating 
current power source. Typically, the electrical connector includes a three 
terminal configuration in which two terminals transfer the current to the 
electrical device, and the third terminal acts as a ground contact for 
safety purposes. As is well understood, an electrical connector of this 
type is engagable with a standard alternating current power outlet so as 
to provide the electrical power to the device. In this manner, the power 
cord can be disengaged from one electrical outlet and re-engaged to 
another electrical outlet in order to enable the electrical device to be 
used at many locations. 
Because the power cord associated with the electrical device is usually 
significantly limited in length, electrical extension cords of differing 
lengths are available such that the electrical device can be used at 
increasing distances from the electrical outlet. As is well understood, an 
extension cord will include electrical connectors at opposite ends of the 
cord which are adapted to be matingly engaged with the connector of the 
power cord of the electrical device and the electrical outlet so as to 
provide the necessary electrical connection. Likewise, several extension 
cords can be attached in this manner to further extend the operating 
distance of the electrical device. 
In many applications, such as in a construction environment, a portable 
electrical tool is moved from location to location within the range of the 
power cord and associated extension cords connected to the tool. As the 
portable tool is being moved from location to location, the cord or cords 
will be constantly encountering obstacles within the work area. Because 
the connectors at the ends of the power cords and the extension cords are 
larger in nature than the cord itself, and because these connectors 
incorporate a number of flat surfaces and hookable edges, the connectors 
get caught up on the obstacles and in some cases electrical power is 
disrupted to the tool because the electrical connectors are separated as a 
result of the tool operator attempting to pull the power cord to a 
desirable location. Therefore, the tool operator must stop his work and 
re-engage the separated connectors. This problem is exacerbated if the 
tool operator is at a location, such as on a platform, which is distant 
from the location where the electrical connection is disengaged. 
Another problem relates to the ability of the connection between the 
connectors to provide a safe connection. As the cord is being dragged 
around in the work area when the tool operator moves from location to 
location, the connection between the connectors may encounter wet areas, 
such as puddles, which could cause water to enter the electrical 
connection area, thus causing a potentially unsafe area against 
electrocution. This also results in great inconvenience to the user of the 
tool since it often results in a blown fuse or circuit breaker which must 
be repaired or reset before continuing work. 
What is needed then is an electrical connector assembly in which engagable 
connectors are rigidly secured such that a relatively large amount of 
force will not separate the electrical connection, and wherein the 
electrical connection is safe from infiltration by moisture. It is 
therefore an object of the present invention to provide such an electrical 
connector assembly. 
SUMMARY OF THE INVENTION 
In accordance with the teachings of the present invention, an electrical 
connector assembly is disclosed for connecting electrical power cords. The 
connector assembly includes a first connector having electrical terminal 
prongs and a second connector having electrical terminal contacts which 
accept the terminal prongs such that the first connector is adaptable to 
engage the second connector in an electrical connection. Each of the 
terminal prongs and the terminal contacts are electrically connected to 
associated power cords including wires for each prong and contact. Each of 
the connectors includes an insulative housing that surrounds the 
connections between the wires and the terminals or the wires and the 
terminal contacts. 
Each of the first and second electrical connectors further includes a 
cylindrical protective housing enclosing the insulative housing. The 
protective housing is bored out such that the insulative housing of the 
respective connector is slidably inserted and rigidly secured within the 
bore proximate one end of the protective housings and the associated cord 
extends from the other end. The protective housing further includes an 
outer threaded portion proximate the bore opening through which the 
insulative housing is inserted. A cylindrical collar is threadably engaged 
to the threaded portions of both of the protective housings in order to 
rigidly secure the electrical connectors together. One of the electrical 
connectors includes a rubber O-ring seated within a channel at one end of 
the connector such that when the first and second electrical connectors 
are engaged, the O-ring seats against the other electrical connector so as 
to provide a water-tight seal for the electrical connection. Each of the 
protective housings are tapered from the end of the housing where the 
connection is made to an opposite end from which the cord extends so as to 
help prevent hang ups on obstacles in a work area. 
Additional objects, advantages, and features of the present invention will 
become apparent from the following description of the appended claims, 
taken in conjunction with the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The following discussion of the preferred embodiments concerning an 
electrical connector assembly is merely exemplary in nature and is in no 
way intended to limit the invention or its applications or uses. 
First turning to FIG. 1, a perspective view of an electrical connector 
assembly 10 according to a preferred embodiment of the present invention 
is shown. The connector assembly 10 includes a first connector 12 and a 
second connector 14 engaged in an electrical connection. The first 
connector 12 and the second connector 14 are rigidly secured together by a 
collar 16 such that the collar 16 encloses connecting ends of the 
connectors 12 and 14 in a manner that will be discussed in detail below. A 
power cord 18 extends from an end of the connector 12 opposite to the 
connector 14. A power cord 20 extends from an end of the connector 14 
opposite to the connector 12. The first connector 12 and the second 
connector 14 each include electrical contacts (shown below) such that when 
the connectors 12 and 14 are engaged, an electrical connection between the 
power cord 18 and the power cord 20 is achieved. 
The first connector 12 and the second connector 14 are tapered such that 
they have a wider diameter at the end which they contact each other and a 
narrower diameter proximate the end from which the cords 18 and 20 extend. 
The tapered configuration of the connector 12 is defined by an outer 
protective housing 22. Likewise, the tapered configuration of the 
connector 14 is defined by an outer protective housing 24. A tip member 26 
extends from the outer housing 22 at the end of the first connector 12 
opposite to the second connector 14, and the power cord 18 extends through 
an opening in the tip member 26. Likewise, a tip member 28 extends from 
the housing 24 at the end of the second connector 14 opposite to the 
connector 12, and the power cord 20 extends through an opening in the tip 
member 28. In a preferred embodiment, the protective housings 22 and 24 
are made of a rigid nylon material. The tip members 26 and 28 are made of 
a softer nylon or rubber material such that the power cords 18 and 20 can 
be flexed against the tip members 26 and 28, respectively, without causing 
damage to the cords 18 and 20. 
FIG. 2 shows a cross sectional view of the connector assembly 10. FIG. 3 
shows an exploded perspective view of the first connector 12. By viewing 
these two figures, the specific components and features of the first 
connector 12 can be seen. The outer protective housing 22 is cylindrical 
in nature and defines a first bore 32 and a second bore 34 extending 
completely through the housing 22. The first bore 32 has a larger diameter 
than the second bore 34 such that a shoulder 36 is formed therebetween. 
The housing 22 includes a barrel portion 40 and a tapered portion 42. A 
series of external threads 44 are integral with the housing 22 at one end. 
The barrel portion 40 is approximately the same length as the bore 32, and 
the tapered portion 42 is approximately the same length as the bore 34. A 
circumferential ring groove 46 is formed in an end face 48 of the housing 
22 proximate to the external threads 44. An O-ring 50 is seated within the 
groove 46, and contacts the electrical connector 14 in a water-tight 
manner which will be discussed in greater detail below. 
An electrical unit 54 is seated within the first bore 32 in a friction fit 
such that a front face 56 of the electrical unit 54 is substantially flush 
with the front face 48 of the housing 22. The electrical unit 54 includes 
an insulative housing 58 for electrically insulating a series of terminal 
contacts 60. The terminal contacts 60 include two alternating current 
contacts and a ground contact, as is well understood in the art. The power 
cord 18 consists of three electrical wires (not shown) which are 
electrically connected to the contacts 60 in a manner that is also well 
understood in the art. The power cord 18 extends from a back surface of 
the electrical unit 54 opposite to the front surface 56. 
The tip member 26 is seated within the second bore 34 in a friction fit. 
The material of the tip member 26 and the friction fit within the second 
bore 34 prevents water from entering the housing 22. The tip member 26 
includes an elongated portion 68 extending through the bore 34 and 
connecting a tapered tip portion 70 and a lip portion 72. The tapered tip 
portion 70 extends from the housing 22 opposite to the front face 48, and 
the lip portion 72 rests against the shoulder 36 within the bore 32. A 
ringed spacer member 74 is in contact with and separates the lip portion 
72 of the tip member 26 from the electrical unit 54. The combinational 
width of the lip portion 72, the spacer member 74 and the electrical unit 
54 make up the length of the bore 32. The electrical unit 54 applies 
pressure against the spacer member 74, which in turn forces the lip 
portion 72 against the shoulder 36 in a water tight engagement. The power 
cord 18 extends through the spacer member 74 and through an internal bore 
76 extending through the tip member 26. The internal bore 76 can be of 
varying diameters in order to accommodate different sized power cords. A 
circumferential groove 78 is formed around a central area of the elongated 
portion 68. A ringed member 80, including but not limited to a zip strap, 
a crimpable hose clamp, or an o-ring, is seated within the groove 78 such 
that the ringed member 80 is tightened in the groove 78 in order to apply 
pressure against the cord 18 so that the cord 18 is snugly secured within 
the elongated portion 68 in a water resistant manner. 
A series of three holes 84 extend through the insulative housing 58. 
Additionally, a series of three holes 86 extends through the lip portion 
72 of the tip member 26 and are aligned with the holes 84 in the 
insulative housing 58. Further, a series of three threaded holes 88 are 
positioned within the shoulder 36 of the housing 22 and are also aligned 
with the holes 84 and 86. A series of three bolts 90, only one of which is 
shown, extend through the holes 84 in the insulative housing 58, through 
the ring spacer member 74, through the holes 86 in the lip portion 72, and 
are threadably engaged with the threaded holes 88 in the shoulder 36. In 
this manner, the electrical unit 54 and the tip member 26 are secured to 
the housing 22. 
FIG. 4 shows an exploded perspective view of the second connector 14. By 
viewing FIGS. 2 and 4, the specific components and features of the second 
connector 14 can therefore be seen. The outer protective housing 24 is 
cylindrical in nature and defines a first bore 100 and a second bore 102 
extending completely through the housing 24. The first bore 100 has a 
larger diameter than the second bore 102 such that a shoulder 104 is 
formed therebetween. The housing 24 includes a barrel portion 106 and a 
tapered portion 108. A series of external threads 110 are integral with 
the barrel portion 106 proximate a front face 112. The barrel portion 106 
is approximately the same length as the bore 100. 
An electrical unit 114 is seated within the first bore 100 in a friction 
fit such that a front face 116 of the electrical unit 114 is substantially 
flush with the front face 112 of the housing 24. The electrical unit 114 
includes an insulative housing 118 for electrically insulating a series of 
three terminal prongs 120. The terminal prongs 120 include two alternating 
current contacts and a ground contact, as iS well understood in the art. 
The power cord 20 consists of three electrical wires (not shown) which are 
electrically connected to the terminal prongs 120 in a manner that is also 
well understood in the art. The cord 20 extends from a back surface of the 
electrical unit 114 opposite to the front surface 112. As can be seen in 
FIG. 2, the base portion 106 of the housing 24 is somewhat shorter than 
the base portion 40 of the housing 22. This is because the electrical unit 
114 is somewhat shorter than the electrical unit 54. 
The tip member 28 is seated within the second bore 102 in a friction fit. 
The material of the tip member 28 and the friction fit within the bore 102 
prevents water from entering the housing 24. The tip member 28 includes an 
elongated portion 126 extending through the bore 102 and connecting a 
tapered tip portion 128 and a lip portion 130. The tapered tip portion 128 
extends from the housing 204 opposite to the front face 112, and the lip 
portion 130 rests against the shoulder 104 within the bore 100. A ring 
spacer member 132 is in contact with and separates the lip portion 130 
from the electrical unit 114. The combinational width of the lip portion 
130, the spacer member 132 and the electrical unit 114 make up the length 
of the bore 100. The electrical unit 114 applies pressure against the 
spacer member 132, which in turn forces the lip portion 130 against the 
shoulder 104 in a water tight manner. The power cord 20 extends through 
the spacer member 132 and through an internal bore 134 extending through 
the elongated portion 126 of the tip member 28. The internal bore 134 can 
be of varying diameters in order to accommodate different sized power 
cords. A circumferential groove 136 is formed around a central location of 
the elongated portion 126. A ring member 138, including but not limited to 
a zip strap, a crimpable hose clamp, or an O-ring, is seated within the 
groove 136 such that the member 138 forces pressure against the cord 20 so 
as to be snugly secured within the elongated portion 126 in a water 
resistant manner. 
A series of three holes 142 extend through the insulative housing 114. 
Additionally, a series of three holes 144 extend through the lip portion 
130 of the tip member 30 and are aligned with the holes 142. Further, a 
series of three threaded holes 146 are threaded within the shoulder 104, 
and are aligned with the holes 142 and 144. A series of three bolts 148, 
only one of which is shown, extend through the holes 142, within the 
ringed spacer member 132, through the holes 144, and are threadably 
secured within the threaded holes 146 so as to rigidly secure the 
electrical unit 114 and the tip member 28 to the housing 24. 
FIG. 5 shows a perspective view of the collar 16. As is apparent, the 
collar 16 is a hollow cylinder. One end of the collar 16 includes a 
tapered portion 152 and an opposite end of the collar 16 includes a 
tapered portion 154. A threaded portion 156 is integral with the underside 
of the collar 16 at the tapered end 154 and a circumferential lip 158 is 
integral with the inside of the collar 16 at the tapered end 152. The 
threaded portion 156 is of such a diameter that it can be slipped over the 
base portion 40 of the housing 22. In a preferred embodiment there are six 
threads per inch for the threaded portion 156, however, the number of 
threads could vary from about 3 and to about 10 threads per inch for the 
threaded portion 156. 
The first connector 12 and the second connector 14 are connected in the 
following manner. Prior to the first connector 12 being connected to the 
second connector 14, the threaded portion 156 is threadably engaged with 
the threaded portion 44 of the housing 22. The terminals 120 of the second 
connector 14 are then inserted into the appropriate terminal contacts 60 
of the first connector 12, in a manner that is well understood in the art. 
The collar 16 is then rotated such that the threaded engagement between 
the threaded portion 156 and the threaded portion 40 advances the collar 
16 towards the second connector 14. As the collar 16 is rotated, the 
threaded portion 156 will eventually threadably engage the threaded 
portion 106 of the housing 24. As the collar 16 is further advanced, the 
lip portion 158 will eventually contact the threaded portion 44 of the 
housing 24 as shown in FIG. 2. When this happens, the front face 112 of 
the housing 26 will be drawn towards the front face 48 of the housing 22, 
and the O-ring 50 will be seated against the front face 112 of the housing 
24 in a water tight engagement. The first connector 12 will then be 
rigidly secured to the second connector 14 in a water resistant manner. It 
will be readily appreciated that the collar 16 will be threadably engaged 
to the threaded portion 44 in order to prevent the collar 16 from slipping 
off of the housing 22 when the first connector 12 is disconnected from the 
second connector 14. The tapered configuration of the housing 22 and the 
housing 24, as well as the collar 16, significantly prevents the connector 
assembly 10 from hanging up on obstacles as it is being drug through a 
work area. 
The foregoing discussion discloses and describes merely exemplary 
embodiments of the present invention. One skilled in the art will readily 
recognize from such discussion, and from the accompanying drawings and 
claims, that various changes, modifications and variations can be made 
therein without departing from the spirit and scope of the invention as 
defined in the following claims.