JP5312432B2 - Power cable connection device and method for assembling the same - Google Patents

Description

  The present invention relates to an improvement in a connecting device for electrically and mechanically connecting ends of a power cable for supplying electric power to various mechanical devices, and an assembling method thereof. Specifically, for a power cable that has a structure that can keep the outer diameter dimension small, can easily perform connection work, can suppress the resistance of the connection part, and can sufficiently secure the mechanical strength of the connection part. A connecting device and an assembling method thereof are realized.

  The ends of power cables used to supply power to various machinery and equipment at various factories and various construction sites or as wiring for large-scale buildings are made of metal with low electrical resistance, such as copper alloys. It is necessary to connect with a connecting device having a connecting terminal. The power cable needs to change the connection state according to the progress of the factory line change, the progress of construction, etc., or the renovation of the building, for example, and therefore it is preferable that the power cable has a structure that can be easily connected. Moreover, in order to keep the power transmission loss low, it is necessary to keep the electrical resistance of the connection part low, and of course, sufficient mechanical strength (especially in order not to come off even when a force in the pulling direction is applied to the power cable) It is necessary to have tensile strength. As a power cable connecting device that satisfies such a requirement, for example, a structure described in Patent Document 1 is known.

[Description of prior art]
6 to 7 show an example of a conventionally known power cable connecting device described in Patent Document 1. FIG. In this conventional structure, a pair of power cables 1 a and 1 b are connected by first and second connection terminals 2 and 3 and a cap nut 4. These connection terminals 2 and 3 are called compression terminals, respectively, and the diameters of the base halves are reduced with the conductors 5a and 5b constituting the power cables 1a and 1b inserted in the base halves. The ends of the power cables 1a and 1b and the connection terminals 2 and 3 are electrically and mechanically connected. These connection terminals 2 and 3 are combined in a state in which the insertion hole 6 and the insertion flange portion 7 formed in the respective first half portions are fitted, and are coupled to each other by the cap nut 4 in a non-separable manner. A rubber spacer is externally fitted to the base of the insertion collar 7 so as to be able to absorb dimensional changes accompanying temperature changes. Further, the periphery of the connecting portion is covered with the annular insulating rubbers 8a and 8b and the insulating sheet 9 to insulate the connecting portion.

  In the case of the conventional structure as described above, even if the cap nut 4 is tightened, the surfaces of the connection terminals 2 and 3 are not strongly pressed against each other. The portion for sending electric power between these connection terminals 2 and 3 is mainly incorporated into the fitting portion, although it depends mainly on the elasticity of the contact that exists in the fitting portion between the insertion hole 6 and the insertion flange portion 7. In order to send a large amount of power depending on the elasticity of the contact, it is necessary to increase the diameter of the fitting portion, and thus the connection terminals 2 and 3. Is disadvantageous.

[Description of Prior Invention]
As a power cable connection device that solves such problems of the prior art and has a structure that can keep the outer diameter size small, can easily perform the connection work, and can keep the resistance of the connection portion low. There is an invention disclosed in 2009-123885. The present invention is an improvement of the previous invention, and since there are many parts in common with the previous invention, first, a power cable connecting device and an assembling method thereof according to the previous invention will be described with reference to FIGS. As shown in FIG. 8, the power cable connecting device according to the present invention includes first and second connecting terminals 2a and 3a, a connecting cylinder 10, and a lock nut 11, each of which is an elastic annular member. It consists of a pair of spring washers 12a, 12b. Each of these members 2a, 3a, 10, 11, 12a, and 12b is made of a metal having a low electrical resistance such as copper or a copper-based alloy. The spring washers 12a and 12b are made of an alloy having a certain degree of elasticity. For this reason, if necessary, the two spring washers 12a and 12b can be made of phosphor bronze or iron alloy.

Among these, the 1st connection terminal 2a is provided with the 1st connection part 13, the insertion collar part 14, the external thread part 15, and the 1st latching | locking part 16, as shown in FIG.
Of these, the first connecting portion 13 is connected and fixed to the end of the conductor 5a constituting one of the power cables 1a and 1b of the pair of power cables 1a and 1b to be connected to each other, which is indicated by a chain line in FIG. It is for doing. In the case of the structure of the prior invention shown in the drawing, the first connection portion 13 is called a compression terminal, like the base half portions of the first and second connection terminals 2 and 3 in the conventional structure described above. At the center, there is a bottomed circular hole 17a that opens to the center of the base end face {the left end face in FIG. 9B). In order to connect the first connection portion 13 and the end portion of the conductor 5a, the end portion of the conductor 5a exposed by removing the end portion of the insulating layer of the power cable 1a in advance is used. It inserts in the said circular hole 17a. Then, by applying a force in the compression direction from the outer diameter side of the first connection portion 13 to reduce the diameter while plastically deforming, the conductor 5a and the first connection terminal 2a are electrically connected. And mechanically connected.

The insertion hook 14 is provided in the front half of the first connection terminal 2a {the right half of FIG. 9B). It is shaped like a circle.
Further, the male screw portion 15 is provided at a portion of the intermediate portion in the axial direction of the insertion flange portion 14 except for a portion near the proximal end (close to the left end in FIG. 9B) close to the first connecting portion 13. It has been. The outer diameter (mountain diameter and valley diameter) of the male screw part 15 is larger than the outer diameter of the insertion collar part 14.
Further, the first locking portion 16 is configured to lock a spanner or a pipe wrench that is a tool for preventing the rotation of the first connection terminal 2a. The portion {the right end portion in FIG. 9B} is provided on the outer peripheral surface.

Further, as shown in FIG. 10, the second connection terminal 3 a includes a second connection portion 18, a screw flange portion 19, and a second locking portion 20.
Of these, the second connecting portion 18 is for connecting and fixing the end of the conductor 5b of the other power cable 1b of the two power cables 1a and 1b to be connected to each other. The terminal 3a is provided at the base end {the right end in FIG. 10A}. Such a second connection portion 18 also employs a structure called a compression terminal, similar to the first connection portion 13. That is, a circular hole 17b is formed at the center of the second connecting portion 18, and a portion exposed from the insulating layer at the end of the conductor 5b can be inserted into the circular hole 17b.
Moreover, the said screw collar part 19 is provided in the intermediate | middle part thru | or the first half part. The specifications (pitch circle diameter, pitch) of the male screw portion formed on the outer peripheral surface of the screw flange portion 19 are the same as the specifications of the male screw portion 15.
Further, the second locking portion 20 is a base end of the second connecting portion 18 for locking a spanner, a pipe wrench or the like which is a tool for preventing the rotation of the second connecting terminal 3a. The portion {the left end portion in FIG. 10A} is provided on the outer peripheral surface.

  Further, as shown in FIG. 11, the connection tube 10 includes a screw hole 21 and a third locking portion 22. Among these, the screw hole 21 is for screwing the male screw portion 15 and the screw flange portion 19, and is provided in a central portion of the connection tube 10 so as to penetrate the connection tube 10 in the axial direction. ing. The third locking portion 22 is provided on the outer peripheral surface of the intermediate portion of the connection cylinder 10 in order to lock a spanner, a pipe wrench, etc., which are tools for rotating the connection cylinder 10.

The lock nut 11 is screwed to the screw flange portion 19.
Also, one of the spring washers 12a and 12b has a spring washer 12a as shown in FIG. 12, which is a portion near the base end of the insertion collar 14, that is, the first connecting portion 13 and the male screw portion. 15 is fitted on the part between. On the other hand, as shown in FIG. 13, the other spring washer 12 b is externally fitted to a portion closer to the tip than the lock nut 11 in the screw flange portion 19.

  Then, as shown in FIG. 8, by screwing the male screw portion 15 into the screw hole 21 and further tightening, between the tip surface of the first connection portion 13 and one end surface of the connection tube 10, The one spring washer 12a is compressed. Further, the screw hook portion 19 is screwed into the screw hole 21 until the front end surface of the screw hook portion 19 abuts on the front end surface of the insertion hook portion 14, and is further tightened. Further, the other spring washer 12 b is compressed between the lock nut 11 and the other end surface of the connecting tube 10 by tightening the lock nut 11 toward the other end surface of the connecting tube 10.

  The power cable connecting device having the above-described structure is assembled by the following procedure. That is, as shown in FIG. 12, the one spring washer 12a is externally fitted in advance to the proximal end portion of the insertion flange 14 of the first connection terminal 2a. In addition, as shown in FIG. 13, the lock nut 11 is screwed in advance to the proximal end portion of the screw flange portion 19 of the second connection terminal 3a, and the connection cylinder 10 is screwed to the intermediate portion or the distal end portion. At the same time, the other spring washer 12 b is sandwiched between the lock nut 11 and the connecting tube 10. As shown in FIG. 13, in a state where the members 3 a, 10, 11, 5 b are combined, the tip end portion of the screw flange portion 19 slightly protrudes from the end opening of the connection tube 10, or It exists inside this end opening (a position recessed toward the middle in the axial direction of the connecting cylinder 10) (when the screw flange 19 is shorter than the illustrated example).

  Therefore, the first unit 28 shown in FIG. 12 and the second unit 29 shown in FIG. 13 are brought close to each other while being concentrically arranged. When the phase of the screw thread formed on the outer peripheral surface of the screw flange portion 19 and the phase of the screw thread constituting the male screw portion 15 are restricted, the distal end surface of the insertion flange portion 14 and the screw flange portion 19 Butt the end face of. If not, the two end surfaces are brought close to each other. Next, the connecting tube 10 is rotated from a state in which the two end surfaces are abutted with each other, or in a state of being opposed to each other, and the connecting tube 10 is moved toward the insertion flange 14. Further, the screw hole 21 and the male screw portion 15 are screwed together and further tightened. The tightening operation is performed by using the spanner locked to the third locking portion 22 while preventing the rotation of the first connection terminal 2a by the spanner locked to the first locking portion 16. This is done by rotating the tube 10. Then, the one spring washer 12a is strongly compressed between the one end face of the connection tube 10 and the front end face of the first connection portion 13.

  Next, the lock nut 11 is moved toward the connection tube 10 while rotating, and further tightened. In this tightening operation, the lock nut 11 is rotated by the spanner locked to the lock nut 11 while the rotation of the second connection terminal 3 a is prevented by the spanner locked to the second locking portion 20. To do. Then, the other spring washer 12b is strongly compressed between the lock nut 11 and the other end face of the connecting cylinder 10.

  According to the power cable connecting device according to the previous invention configured as described above, it can be manufactured at low cost without using a part having a special shape. That is, each of the first connection terminal 2a, the second connection terminal 3a, the connection cylinder 10, the lock nut 11, and the pair of spring washers 12a and 12b constituting the power cable connection device is provided. Since they have a simple shape, they are easy to process and can be manufactured at low cost. Further, by configuring each of the components 2a, 3a, 10, and 11 to have a cross-sectional shape based on a circle, the outer diameter can be reduced while ensuring the necessary strength.

  Moreover, the operation | work which assembles the connection apparatus for electric power cables combining each member 2a, 3a, 10, 11, 12a, 12b is carried out to the outer peripheral surface of the 1st-3rd latching | locking parts 16, 20, and 22 and the lock nut 11. This can be done easily by locking the spanner and rotating the connection tube 10 and the lock nut 11 while preventing the rotation of the first and second connection terminals 2a and 3a. Further, the power cables 1a and 1b are not twisted so as to cause a problem in connection with the connection work. For this reason, connection work can be performed easily. In the state where the assembling work is completed, one side surface of the male screw thread constituting the male screw part 15 and the screw thread part 19 and one side surface of the female screw thread constituting the screw hole 21 are the male screw part 15 and the screw collar part. Strong contact is made based on the tightening of the screw holes 21 and the screw holes 21. In this way, in a state where the side surfaces of the respective screw threads are in strong contact with each other, the first and second connection terminals 2a and 2a and the connection tube 10 are in an electrically reliably connected state. The resistance of the connection part can be kept low. In addition, the mechanical strength of the connecting portion can be sufficiently secured.

Further, the male screw portion 15 and the screw engagement portion 19 and the screw hole 21 may loosen carelessly based on the tightening of the lock nut 11 and the elasticity of the pair of spring washers 12a and 12b. Absent. For this reason, the electrical resistance of the said connection part can be suppressed low, and the state which fully ensured the mechanical strength of the connection part can be maintained stably over a long period of time.
Further, as shown in FIG. 13, prior to the assembly work, the second connection terminal 3a, the lock nut 11, the spring washer 12b, and the connection tube 10 are connected to a manufacturing plant for a power cable connection device or the like. If it is combined in advance, the work at the assembly site of the power cable connecting device can be facilitated. Moreover, the assembly work is not disabled by losing the parts.

  The power cable connecting device and its assembling method according to the prior invention as described above are designed to reduce the outer diameter and reduce the size and weight, keep the resistance of the connecting portion low, and increase the mechanical strength of the connecting portion. A sufficient effect can be obtained from the aspect of securing. However, there is room for improvement in terms of facilitating connection work. Moreover, there is still room for improvement in terms of shortening the axial dimension in terms of size and weight reduction.

  In view of the circumstances as described above, the present invention aims to reduce the outer diameter size to reduce the size and weight, suppress the resistance of the connection portion, and secure the mechanical strength of the connection portion. The present invention was invented to facilitate the connection work without impairing the functions and effects obtained by the invention and to further reduce the size and weight by reducing the axial dimension.

  Of the power cable connecting device and the assembling method thereof according to the present invention, each of the power cable connecting devices described in claim 1 is made of a metal having a low electrical resistance, such as copper or a copper-based alloy. It consists of a connection terminal, a second connection terminal, a connection tube, a lock nut, and a pair of elastic annular members.

Among these, the 1st connection terminal is provided with a 1st connection part and a connection collar part.
Of these, the first connection terminal is provided in the base half, a first connection portion for connecting and fixing the end of one of the power cables to be connected to each other, A connecting collar provided in the first half.
In addition, the connecting rod portion includes at least a male screw portion provided at an axially intermediate portion, a male screw portion provided at an axial tip portion in a state continuous from the male screw portion, and a distal end side having a smaller diameter than the male screw portion. A cylindrical portion.

  Further, the second connection terminal is provided at the base end portion, a second connection portion for connecting and fixing the end portion of the other power cable of the pair of power cables to be connected to each other, The tip side cylindrical part provided in a state where it opens to the center of the front end surface of the screw hook part can be inserted into the screw hook part provided in the middle part or the front half part and the tip part of the screw hook part. And a concave hole for positioning.

Further, the connection tube includes a screw hole provided in a state of penetrating in the axial direction in a center portion for screwing the male screw portion and the screw flange portion.
Further, the lock nut is screwed onto the screw flange portion.
The two elastic annular members are members such as a spring washer and a disc spring that are elastically compressible in the axial direction. One elastic annular member of such a pair of elastic annular members is provided at a peripheral portion of the base-end-side cylindrical portion, and the other elastic annular member is provided at a distal end of the screw flange portion with respect to the lock nut. The outer parts are fitted on the side portions.
Then, in a state where the distal end side cylindrical portion is inserted into the positioning concave hole, the male screw portion is screwed into the screw hole and further tightened, whereby one end surface of the first connecting portion and one of the connecting cylinders are connected. The one elastic annular member is compressed between the end faces.
Further, by tightening the lock nut toward the other end surface of the connection tube in a state where the screw flange portion is screwed into the screw hole, the other end surface between the lock nut and the other end surface of the connection tube is The elastic annular member is compressed.

According to a second aspect of the present invention, there is provided a method for assembling the power cable connecting device according to the first aspect of the present invention. The one elastic annular member is externally fitted. In addition, the lock nut is screwed in advance to the base end portion of the screw flange portion of the second connection terminal, and the connection cylinder is screwed to the intermediate portion or the distal end portion, and between the lock nut and the connection tube. The other elastic annular member is held between the two.
In addition, when the axial distance between the distal end surface of the screw flange and the axial end surface of the connecting cylinder is smaller than the axial height of the distal end cylindrical portion, the distal end cylindrical portion is moved to the positioning recess. By inserting it into the hole, the central axis of the first connection terminal is aligned with the central axis of the second connection terminal and the connection cylinder.
Thereafter, by rotating the connecting cylinder and moving the connecting cylinder toward the male threaded portion, the screw hole on the inner peripheral surface of the connecting cylinder and the male threaded portion are screwed together and further tightened. The one elastic annular member is compressed between one end face of the tube and the front end face of the first connecting portion.
Next, while rotating the lock nut, the lock nut is moved toward the connection tube and further tightened, and the other elastic annular member is compressed between the lock nut and the other end surface of the connection tube.

  According to the power cable connecting device of the present invention configured as described above, it can be manufactured at low cost without using parts having a special shape. That is, since the first connection terminal, the second connection terminal, the connection cylinder, the lock nut, and the pair of elastic annular members that constitute the power cable connection device have simple shapes. All are easy to process and can be manufactured at low cost. Further, by configuring each component in a cross-sectional shape based on a circle, the outer diameter can be reduced while ensuring the necessary strength. In addition, the operation of assembling the power cable connecting device by combining the respective members is performed by locking a tool such as a spanner on the outer peripheral surfaces of the first to third locking portions and the lock nut (the first to third locking devices). If all or part of the locking portion is omitted, a tool such as a pipe wrench is locked on the outer peripheral surface of the omitted member) to prevent the first and second connection terminals from rotating. However, it can be easily performed by rotating the connecting cylinder and the lock nut. Further, since the cable is not twisted during the connection work, the connection work can be easily performed. Then, in the state where the assembly work is completed, one side surface of the male screw thread constituting the male screw part and the screw thread part and one side surface of the female thread thread constituting the screw hole are the male screw part, the screw collar part and the screw hole. Strong contact is made based on the tightening. In this way, in the state where the side surfaces of the respective screw threads are in strong contact with each other, the first and second connection terminals and the connection tube are in a state of being reliably connected electrically, and the resistance of the connection portion Can be kept low. In addition, the mechanical strength of the connecting portion can be sufficiently ensured. Further, the male screw portion and the screw engagement portion between the screw collar portion and the screw hole are not loosened carelessly based on the tightening of the lock nut and the elasticity of the both elastic annular members. For this reason, the resistance of the connecting portion can be kept low, and a state in which the mechanical strength of the connecting portion is sufficiently secured can be stably maintained over a long period of time.

Further, as in the assembling method described in claim 2, prior to the assembling work, the second connecting terminal, the lock nut, the elastic annular member, and the connecting cylinder are pre-combined at a manufacturing factory of the connecting device for the power cable. Then, the work at the assembly site of the power cable connecting device can be facilitated. Moreover, the assembly work is not disabled by losing the parts.
The above operations and effects are the same as those of the above-described prior invention, and according to the present invention, the same effects as those of the above-described prior invention can be obtained.
In particular, in the case of the power cable connecting device and the method of assembling the same according to the present invention, prior to screwing the male screw portion and the screw cylinder, the tip side cylindrical portion is inserted into the second positioning concave hole. By inserting, the central axis of the first connection terminal and the central axes of the second connection terminal and the connection cylinder can be easily matched.
For this reason, the connection work of said 1st and 2nd terminals which connected each to the edge part of an electric power cable can be made easier compared with the previous invention mentioned above.

The half section side view which shows one example of embodiment of this invention in the state after completion of an assembly. The half part cutting side view of a 1st connection terminal. The half part side view of the 2nd connecting terminal. The half part side view of a connection cylinder. The half part cutting side view which shows the state in the middle of assembling combining each member of a structure. The disassembled perspective view which shows an example of a conventional structure. Sectional drawing shown in the assembled state. The side view which shows one example of the structure which concerns on a prior invention. Similarly, an end view (A) and a side view (B) of the first connection terminal. Similarly, the side view (A) and end view (B) of the second connection terminal. Similarly, XX sectional drawing (B) of the side view (A) and (A) of a connection cylinder. The side view which shows the state which combined the 1st connection terminal and the spring washer similarly. Similarly, the side view which shows the state which combined the 2nd connection terminal, the connection pipe | tube, the spring washer which is an elastic annular member, and the lock nut.

  1 to 5 show an example of an embodiment of the present invention. In addition, the feature of this example is that the work of connecting the two connection terminals 2b and 3b is made easier by devising the shape of the first half of the first and second connection terminals 2b and 3b. Thus, the axial dimension of the power cable connecting apparatus as a whole can be shortened by shortening the axial dimension of the connecting cylinder 10a. Since the configuration and operation of the other parts are the same as those of the previous invention described above, explanations regarding the equivalent parts will be omitted or simplified, and the following will focus on the characteristic parts of this example.

The connection flange 23 provided in the first half of the first connection terminal 2b includes a proximal end side cylindrical portion 24, a male screw portion 15a, and a distal end side cylindrical portion 25.
Among these, the base end side cylindrical part 24 is provided in the part near the 1st connection part 13 which is a compression terminal. In addition, this base end side cylindrical part 24 can also be abbreviate | omitted.
Further, the male screw portion 15 a is provided at an axially intermediate portion in a state of being continuous from the proximal end side cylindrical portion 24, and has a larger diameter than the proximal end side cylindrical portion 24.
Further, the distal end side cylindrical portion 25 is provided at the axial distal end portion in a state of being continuous from the male screw portion 15 a and has a smaller diameter than the proximal end side cylindrical portion 24.

  Further, a positioning concave hole 26 is provided in a screw hole portion 19a provided in an intermediate portion or a front half portion of the second connection terminal 3b so as to open at a central portion of the tip end surface of the screw flange portion 19a. . An inner diameter of the positioning concave hole 26 is slightly larger than an outer diameter of the distal end side cylindrical portion 25 (for example, about several tens to several hundreds of μm), and the distal end side cylindrical portion 25 is made to be the positioning concave hole. 26 can be inserted almost without rattling. In addition, the depth D of the positioning concave hole 26 is larger than the height H of the leading end side cylindrical portion 25 (D> H), and the leading end side cylindrical portion 25 is placed in the positioning concave hole 26. I'm trying to insert it. Further, the first and second connection terminals 2b and 3b are substantially concentric with each other in the inserted state. In order to facilitate the operation of inserting the distal end side cylindrical portion 25 into the positioning concave hole 26, the outer peripheral edge portion of the distal end surface of the distal end side cylindrical portion 25 and the opening of the positioning concave hole 26 are provided. At least one of the peripheral edge portion is chamfered.

  In addition, the connecting tube 10a is provided with a screw hole 21a in the central portion so as to penetrate in the axial direction in the same manner as the connecting tube 10 (see FIGS. 8, 11 and 13) constituting the above-described invention. The pitch and pitch circle diameter of the screw hole 21a, the male screw portion 15a, and the screw flange portion 19a are the same, and the male screw portion 15a and the screw flange portion 19a are screwed into the screw hole 21a. Like. In the state where the assembly of the power cable connecting device is completed, as in the case of the above-described prior invention, as shown in FIG. 1, the front end surface of the first connecting portion 13 of the first connecting terminal 2b and the connecting tube One spring washer 12a is crushed elastically between one axial end face of 10a. Further, the other spring washer 12b is elastically crushed between the other axial end surface of the connecting tube 10a and the lock nut 11. In this state, the axial side surface of the male screw thread constituting the male screw portion 15a and the screw flange portion 19a strongly contacts the axial side surface of the female screw thread forming the screw hole 21a. And the electrical resistance of the contact portion between the first and second connection terminals 2b, 3b and the connection tube 10a is kept low.

  In the case of this example, the male screw is inserted in the state where the distal end side cylindrical portion 25 on the first connection terminal 2b side is fully inserted into the positioning concave hole 26 on the second connection terminal 3b side. The portion 15a and the screw flange portion 19a are abutted at the respective axial end surfaces. As in the structure of the above-described prior invention, the distal end portion (see FIG. 8) of the insertion flange portion 14 does not exist between the male screw portion 15 and the screw flange portion 19. Therefore, the axial length of the connecting cylinder 10a constituting the structure of this example can be made shorter than the connecting cylinder 10 constituting the structure of the previous invention. For this reason, it is possible to shorten the axial dimension as compared with the structure of the prior invention, and it becomes easier to reduce the size and weight compared to the structure of the prior invention.

  When assembling such a structure of this example, first, the screw flange portion 19a provided in the front half of the second connection terminal 3b is screwed into the connection cylinder 10a. And as shown in FIG. 5, between the front end surface of this screw collar part 19a and the axial direction both end surfaces of this connection pipe | tube 10a, it is the one end surface (left end surface of FIG. 5) by the side of said 1st connection terminal 2b. The axial distance L is made sufficiently smaller (L << H) than the axial height H of the distal end side cylindrical portion 25. Preferably, the tip end surface of the screw flange portion 19a is positioned on the same plane as the one end surface of the connection tube 10a or slightly protrudes from the one end surface. In this state, the distal end side cylindrical portion 25 is inserted into the positioning concave hole 26. By this insertion operation, the central axis of the first connection terminal 2b can be aligned with the central axes of the second connection terminal 3b and the connection cylinder 10a. By making the central axes of these members 2b, 3b, and 10a coincide with each other, the male screw portion 15a of the first connection terminal 2b and the screw hole 21a of the connection tube 10a that are not yet screwed in this state. Can be easily screwed together.

Therefore, by rotating the connection tube 10a toward the male screw portion 15a, the screw hole 21a on the inner peripheral surface of the connection tube 10a and the male screw portion 15a are screwed and further tightened. The one spring seat plate 12a is elastically compressed between one axial end surface of the connection tube 10a and the front end surface of the first connection portion 13. Next, the lock nut 11 is rotated and moved toward the connection tube 10a and further tightened, and the other spring seat plate 12b is elastically moved between the lock nut 11 and the other end surface of the connection tube 10a. Compress. FIG. 5 shows the axial distance L for convenience of explanation, but in order to actually realize the state shown in FIG. 5, the connection cylinder 10a is attached to the first tube after L≈0. Move toward the connection terminal 2b.
In the case of the assembly method of the present example performed as described above, the central axis of the first connection terminal 2b and the central axes of the second connection terminal 3b and the connection cylinder 10a are easily matched. As a result, the connection work between the first and second terminals 2b and 3b, each of which is connected to the end of the power cable, can be made easier than in the previous invention.

  In carrying out the present invention, when connecting the conductors 5a and 5b of the power cables 1a and 1b to the first and second connection portions 13 and 18 provided in the first and second connection terminals 2b and 3b, respectively. In some cases, the first and second connecting portions 13 and 18 may be compressed with a hexagonal die. In this case, the shape of the outer peripheral surfaces of the first and second connecting portions 13 and 18 after compression is a hexagon, and a tool such as a spanner can be locked as it is. Therefore, the outer peripheral surfaces of the first and second connection portions 13 and 18 having such a shape are used as they are to stop the rotation of the first and second connection terminals 2b and 3b. It can also be used as On the other hand, a plurality of flat surfaces 27, 27 are formed on the outer peripheral surface of the connecting tube 10a, similar to the third locking portion 22 (see FIGS. 8 and 11) having the conventional structure described above. It is preferable to use a locking portion for locking a tool for rotating the connecting cylinder 10a. However, when a pipe wrench is used as a tool for preventing or rotating each member 2b, 3b, 10a, the outer peripheral surface of each member 2b, 3b, 10a is simply a cylindrical surface. It can be left as it is.

Further, the outer peripheral surfaces of the first and second connection terminals 2b and 3b and the connection cylinder 10a can be plated with tin (Sn) or the like as required.
Further, after assembling the power cable connecting device shown in FIG. 1, the power cable connecting device is covered with an insulating tube made of an elastic material such as rubber as necessary. As is well known, for example, as described in Patent Document 2, this insulating cylinder is arranged in advance around one of the power cables in a state of being fitted around the holding sleeve. After assembling the power cable connection device, the power cable connection device is moved around the power cable connection device, and then the holding sleeve is removed. As a result of this extraction, the diameter of the insulating cylinder is elastically reduced, and the power cable connecting device is secured from the insulation layer at the ends of the conductors 5a and 5b, together with the portions exposed from the insulating layer, and Covered with watertightness. In addition, for the insulation treatment of the power cable connecting device, in addition to externally fitting the insulating tube, an insulating heat-shrinkable tube is closely fitted or an insulating tape is wound. You can also do it. Insulation treatment using a heat-shrinkable tube is effective for processing in a narrow place, and insulation treatment using an insulating tape is effective in terms of cost reduction.

1a, 1b Power cable 2, 2a, 2b First connection terminal 3, 3a, 3b Second connection terminal 4 Cap nut 5a, 5b Conductor 6 Insertion hole 7 Insertion flange 8a, 8b Insulation rubber 9 Insulation sheet 10, 10a Connection cylinder 11 Lock nut 12a, 12b Spring washer 13 First connection portion 14 Insertion flange portion 15, 15a Male thread portion 16 First locking portion 17a, 17b Circular hole 18 Second connection portion 19, 19a Screw flange portion 20 2nd latching | locking part 21, 21a Screw hole 22 3rd latching | locking part 23 Connection collar part 24 Base end side cylindrical part 25 Front end side cylindrical part 26 Positioning concave hole 27 Flat surface 28 1st unit 29 2nd unit

JP 2008-198509 A JP 2001-353780 A

Claims (2)

A first connection terminal, a second connection terminal, a connection tube, a lock nut, and a pair of elastic annular members, each of which is elastically compressible in the axial direction, each made of a conductive material Consisting of
Of these, the first connection terminal is provided in the base half, a first connection portion for connecting and fixing the end of one of the power cables to be connected to each other, A connecting hook provided in the first half, and this connecting hook is provided at the axially leading end in a state continuous from the male screw provided at least in the axial middle part, It is equipped with a cylindrical part on the tip side smaller in diameter than this male thread part,
The second connection terminal is provided at the base end portion, a second connection portion for connecting and fixing the end portion of the other power cable of the pair of power cables to be connected to each other, and an intermediate portion Positioning that can be inserted into the tip of the screw rod provided at the front half and the tip of the screw rod at the center of the tip of the screw hook With a concave hole for
The connecting cylinder is provided with a screw hole for screwing the male screw portion and the screw flange portion provided in a state of penetrating in the axial direction in the center portion,
The lock nut is screwed to the screw flange portion,
One elastic annular member of the two elastic annular members is in the peripheral portion of the base end side cylindrical portion, and the other elastic annular member is in the screw flange portion closer to the tip than the lock nut. Each is fitted,
With the male threaded portion screwed into the screw hole and further tightened in a state where the distal end side cylindrical portion is inserted into the positioning concave hole, the distal end surface of the first connecting portion and one end surface of the connecting cylinder The one elastic annular member is compressed between,
By tightening the lock nut toward the other end surface of the connection tube in a state where the screw flange portion is screwed into the screw hole, the other elastic force is provided between the lock nut and the other end surface of the connection tube. A connecting device for a power cable compressing an annular member. A method for assembling the power cable connecting device according to claim 1,
The one elastic annular member is externally fitted in advance to the base end portion of the first connection terminal, and a lock nut is attached to the base end portion of the screw collar portion of the second connection terminal in advance. The connection tube is screwed to the tip portion, and the other elastic annular member is sandwiched between the lock nut and the connection tube,
With the axial distance between the distal end surface of the threaded collar portion and the axial end surface of the connecting cylinder smaller than the axial height of the distal end side cylindrical portion, the distal end side cylindrical portion is used as the positioning concave hole. By inserting, after making the central axis of the first connection terminal coincide with the central axis of the second connection terminal and the connection cylinder,
By rotating the connecting tube and moving the connecting tube toward the male threaded portion, the screw hole on the inner peripheral surface of the connecting tube and the male threaded portion are screwed together and further tightened, and one end of the connecting tube is secured. Compressing the one elastic annular member between the end surface and the front end surface of the first connecting portion;
Next, a method for assembling the power cable connecting device for compressing the other elastic annular member between the lock nut and the other end face of the connecting tube by rotating the lock nut toward the connecting tube and further tightening the lock nut .

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