JP5637228B2 - Energization control device for electric fusion joint - Google Patents

Description

  The present invention relates to an energization control device for an electric fusion joint used when a thermoplastic resin pipe is fusion-bonded using an electric fusion joint.

  Conventionally, an electric fusion joint is generally used for fusion bonding of thermoplastic resin pipes such as polyethylene pipes. The electric fusion joint is a joint in which a heating wire is embedded inside the joint.

  In the electric fusion joint, in order to pass electricity through the heating wire embedded inside, the tip end of the output cable (connector) connected to the current controller is connected to the electric fusion joint for connecting the heating wire. Two insertion ports (terminals) are installed for each joint.

  There are two methods for controlling the fusion time of an electric fusion joint: a self-control method and a time control method. There are two self-control methods, a pressure detection method is proposed in Japanese Patent Laid-Open No. 60-198224, and a temperature detection method is proposed in Japanese Patent Laid-Open No. 4-366088.

  In addition, there are two other time control methods, and an identification resistance reading method is proposed in Japanese Patent Laid-Open No. 5-522288, and a barcode time control method is proposed in Japanese Patent No. 2739578. ISO has been established on the basis of the Japanese Patent No. 2739578, and when a barcode time control system is used, it is common to install a barcode label conforming to ISO 13950 / TR on an electric fusion joint.

  At present, each electric fusion joint manufacturer in Japan employs (1) pressure detection method, (2) temperature detection method, (3) identification resistance reading method, and different fusion time control methods.

  In addition, each manufacturer's electric fusion joints have different fusion time control methods, and at the same time, the outer diameter of the joint terminal male electrode part and the inner diameter of the terminal insertion part, which are parts to be engaged with the power supply control device, are different. ing.

  Conventionally, since a dedicated controller is required for each fusion time control method, the shape of the joint terminal differs from manufacturer to manufacturer, and the current controller and joint have a one-to-one relationship. There was no need to ensure compatibility through proper use.

  In the bar code time control method that has been used in Europe and America in recent years and is also introduced in Japan, an electric fusion joint with a bar code label that conforms to ISO 13950 / TR is used. Since joints can also be fused, it is predicted that electric fusion joints compatible with the (4) bar code time control method will become widespread in the future.

  As a fusion time control method, if it is an electric fusion joint with a bar code label conforming to ISO, the fusion time control can be performed by a barcode time control type energization control device.

  However, the connector shape at the end of the output cable of each manufacturer's bar code time control energization control device is the terminal of the current electric fusion joint to ensure compatibility between the conventional energization control device manufacturer and the joint manufacturer. Since the shape is conventional, the electrode part shape of the connector is a conventional electrode part shape.

  In order to be able to connect to such a joint terminal of each manufacturer, as disclosed in Japanese Patent Laid-Open No. 2000-208219, the terminal terminal connected to the heating wire of the electric fusion joint, and the current to this There has been proposed a terminal adapter for connecting a terminal connector connected to a power cord of an electric fusion apparatus.

  Further, in order to fuse electric fusion joints having different fusion control methods with the same energization control device, as disclosed in JP-A-11-320689, a plurality of joint terminal insertion ports and sensors are provided in the connector. Has been proposed.

JP-A-60-198224 JP-A-4-366088 JP-A-5-522288 Japanese Patent No. 2739578 JP 2000-208219 A JP 11-320689 A

  When an electric fusion joint of a different manufacturer is used to perform fusion work using an energization control device that also has one bar code time control method, an adapter suitable for the joint is required.

  However, when the adapter is used, the number of connection points is doubled compared to when the adapter is not used. For this reason, the contact resistance in a connection part increases. In an electric fusion joint that needs to efficiently supply electric energy to the heating wire of the electric fusion joint, reducing the contact resistance as much as possible leads to quality improvement.

  Further, the adapter body is small when considering the connection with the joint electrode, and therefore, the adapter body is likely to be lost during use.

  In order to ensure compatibility with different fusion time control systems, it has been proposed to provide an electrode, a sensor for pressure detection, and a sensor for temperature detection in the same connector.

  However, since the shape is very complicated and bulky, there is a problem that workability is not good when connecting to the terminal portion of the electrofusion joint in a limited space such as embedded.

  In addition, since it is necessary to mount a system corresponding to a plurality of energization control methods in the same energization control device, there is a problem that the energization control device is very expensive and heavy.

  Accordingly, an object of the present invention is to provide an energization control device for an electric fusion joint that can solve the above-mentioned problems and can easily and safely connect power cables of electric fusion joints of different types of terminals. There is to do.

In order to achieve the above object, the present invention has the following features.
[1] A current-carrying control device for an electric fusion joint used for joining an electric fusion joint and a resin pipe, which is provided around a connector and a first electrode disposed on the main body of the connector. A first connector insertion portion and a second connector insertion portion provided around the second electrode, wherein each of the first electrode and the second electrode is provided in an electric fusion joint. A first terminal electrode provided in the inserted portion and a second terminal electrode provided in the second terminal inserted portion can be fitted to the first connector inserted portion and the second connector inserted portion. Can be inserted into the first terminal insertion portion and the second terminal insertion portion, respectively, and the first connector insertion portion cannot be inserted into the second terminal insertion portion. The second The electrode is incapable of fitting with the first terminal electrode, whereby the first electrode and the second electrode can be connected only to the first terminal electrode and the second terminal electrode, respectively. An energization control device for an electric fusion joint.
[2] The second terminal insertion part is a concave insertion part, and an inner diameter thereof is smaller than an outer diameter of the first connector insertion part. Energization control device for electric fusion joints.
[3] The second electrode and the first terminal electrode are a female electrode and a male electrode, respectively, and an inner diameter of the second electrode is smaller than an outer diameter of the first terminal electrode. The energization control device for an electric fusion joint according to claim 1 or 2.

  According to the present invention, the following useful effects are brought about.

  (1) Since the electrodes of the connector are arranged symmetrically with the connector body in between, it is possible to easily select the electrode to be used. Without selection, and the power cable can be connected to the electric fusion joint. Also, joints from different manufacturers can be used together, and electrofusion bonding can be performed by the same energization control device.

  (2) Since the adapter is not used by providing the connector with a plurality of electrodes, it is possible to perform the electric fusion bonding quickly without changing the adapter. Also, the connector itself is very small and it is very easy to connect to the terminal.

  (3) Since an electric shock prevention function using a simple mechanism called an electrode guard rod is provided, the risk of electric shock can be eliminated and safety can be ensured without increasing the size of the connector. Furthermore, foreign matters such as mud are difficult to enter by the electrode guard rod closing the electrode space on the non-connection side. As a result, an increase in contact resistance between the electrodes of the connector and the terminal is prevented, and rusting of the electrode surface due to moisture contained in mud or the like is prevented.

  (4) By defining the shape and dimensions of the electrode of the connector electrode portion and the connector insertion port, it is possible to prevent erroneous connection to the terminal of the non-connection-side electrofusion joint.

It is a top view of the connector which concerns on embodiment of this invention. It is a side view of the connector which concerns on embodiment of this invention. It is a side view which shows the electrode guard stick | rod which concerns on embodiment of this invention. It is explanatory drawing which shows the connection of the electricity supply control apparatus which concerns on embodiment of this invention, and an electrofusion joint. It is sectional drawing which shows the state which connected the 1st electrode of the connector which concerns on embodiment of this invention, and the terminal of the 1st electrofusion joint (made by A company). It is sectional drawing which shows the state which connected the 2nd electrode of the connector which concerns on embodiment of this invention, and the terminal of the 2nd electrofusion joint (made by B company). It is sectional drawing which shows the state which cannot connect the 1st electrode of the connector which concerns on embodiment of this invention, and the terminal of a 2nd electric fusion joint (made by B company). It is sectional drawing which shows the state which cannot connect the 2nd electrode of the connector which concerns on embodiment of this invention, and the terminal of a 1st electrofusion joint (made by A company). It is explanatory drawing which shows the Example of this invention which carries out the fusion | melting joining of the thermoplastic resin pipe | tube using an electric fusion joint.

  Next, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a plan view of a connector according to an embodiment of the present invention, FIG. 2 is a side view, FIG. 3 is a side view showing an electrode guard rod, and FIG. FIG. 5 is a cross-sectional view showing a state in which the first electrode of the connector and the terminal of the first electrofusion joint (manufactured by Company A) are connected, and FIG. FIG. 7 is a cross-sectional view showing a state in which a terminal of a fitting joint (manufactured by B company) is connected, and FIG. FIG. 8 is a cross-sectional view showing a state where the second electrode of the connector and the terminal of the first electrofusion joint (manufactured by Company A) cannot be connected.

  As shown in FIG. 4, the electric fusion joint 2 (the electric fusion joint 21 manufactured by Company A and the electric fusion joint 22 manufactured by Company B) is an electric conduction control device for electric fusion joints (hereinafter referred to as “electric conduction control device”). 2 ”are provided with two power cables (output cables) 6 and 6, and a connector (insertion port) 4 is provided at the tip thereof. The electric fusion joint 2 is fitted on the outer side of the ends of the tubes 3 and 3. The electric fusion joint 2 is provided with two terminals 5, and the power cable 6 is connected to the connector 4 and the terminal 5.

  As shown in FIGS. 5 to 8, the connector 4 is disposed symmetrically on both sides of the connector body 4 a and the connector body 4 a. In FIGS. 2 and 5 to 8, the connector body 4 a is sandwiched. The first electrode 7 (hereinafter referred to as “electrode 7”) and the second electrode 8 (hereinafter referred to as “electrode 8”) are provided symmetrically on both sides. The electrode 7 is a cylindrical female electrode, and a connector insertion portion (first connector insertion portion) 17 made of a cylindrical non-conductor is disposed around the electrode 7. The electrode 8 is a cylindrical female electrode having a smaller inner diameter than the female electrode 7, and a cylindrical non-cylindrical electrode having an outer diameter smaller than that of the connector insertion portion 17 around the electrode 8. A connector insertion portion (second connector insertion portion) 18 made of a conductor is disposed. And the female electrode 7 and the electrode 8 are arrange | positioned so that a mutual axis may become uniaxial. The female electrodes 7 and 8 are made of, for example, brass. The connector insertion parts 17 and 18 are made of, for example, resin.

  In the electric fusion joint 2 {21 (Company A), 22 (Company B)}, the electrode standard of the terminal 5 (51, 52) differs depending on the joint manufacturer, but the electrode 7 of the connector 4 is the electric fusion joint 21 (A The electrode 8 is manufactured so as to meet the specifications of the electric fusion joint 22 (Company B), and the electrode 7 or the electrode 8 is selected and used according to the electric fusion joint.

   As shown in FIGS. 5 to 8, a power cable 6 is connected to the connector body 4a. A stopper 9 made of a conductor is provided in the connector main body 4 a, and the stopper 9 connects the electrodes 7 and 8 and the power cable 6. Furthermore, the stopper 9 is a substantially box-like body, and is made of a non-conductive material, such as a resin, on the upper and lower sides (in the drawings of FIGS. 5 to 8), that is, on the electrode 7 side and the 8 side, respectively. Holes 9a and 9b for inserting the electrode guard rod 10 are perforated.

  The electrode guard rod 10 has a large diameter portion 10a having an outer diameter that can be inserted into the electrode 7, a small diameter portion 10b having an outer diameter that can be inserted into the electrode 8, and an outer diameter larger than the inner diameters of the holes 9a and 9b. And a central portion 10c having The hole 9a of the stopper 9 has a slightly larger inner diameter than the large-diameter portion 10a of the electrode guard rod 10, and the hole 9b of the stopper 9 has a slightly larger inner diameter than the small-diameter portion 10b of the electrode guard rod 10, thus The large-diameter portion 10a of the electrode guard rod 10 can pass through the hole 9a, and the small-diameter portion 10b of the electrode guard rod 10 can pass through the hole 9b. Further, since the outer diameter of the central portion 10c of the electrode guard rod 10 disposed in the stopper 9 is larger than the inner diameters of the holes 9a and 9b, the electrode guard rod 10 does not come out of the stopper 9.

  The small-diameter portion 10b of the electrode guard rod 10 is inserted into the electrode 8 through the hole 9b, and the large-diameter portion 10a is inserted into the electrode 7 through the hole 9a. It is blocked. The vertical height of the central portion 10c of the electrode guard rod 10 shown in FIGS. 5 to 8 is smaller than the vertical height inside the stopper 9 by a predetermined dimension. The electrode guard rod 10 has a central portion 10c. However, it can move up and down by the distance that can move up and down in the stopper 9. Thus, the small-diameter portion 10b of the electrode guard rod 10 can slide up and down in the electrode 8 and the large-diameter portion 10a in the electrode 7, respectively. When the electrode guard rod 10 moves to the electrode 7 side, the large-diameter portion 10a closes the space inside the electrode 7, while when the guard rod 10 moves to the electrode 8 side, the small-diameter portion 10b moves inside the electrode 8. Block the space.

  Next, the terminal 5 (51, 52) of the electric fusion joint 2 (21, 22) will be described. A terminal 51 is installed in the electric fusion joint 21 (Company A) (see FIGS. 5 and 8). On the other hand, the terminal 52 is installed in the electric fusion joint 22 (Company B) (see FIGS. 6 and 7).

  The terminal 51 can be fitted to the electrode 7 of the connector 4 and cannot be fitted to the electrode 8 (see FIGS. 5 and 8). On the other hand, the terminal 52 can be fitted to the electrode 8 of the connector 4 and cannot be fitted to the electrode 7 (see FIGS. 6 and 7).

  As shown in FIGS. 5 and 8, the terminal 51 is a concave terminal made of a non-conductive material (same material as the main body of the electrofusion joint 21) for inserting the connector insertion portion 17 of the electrode 7 of the connector 4. A plug-in portion (first terminal plug-in portion) 12 and a male electrode (first terminal electrode) 11 provided in the terminal plug-in portion 12 and capable of fitting with the electrode 7 are provided. Yes. The inner diameter of the terminal insertion part 12 has a predetermined dimension into which the connector insertion part 17 of the electrode 7 can be inserted.

  As shown in FIGS. 6 and 7, the terminal 52 is a concave terminal made of a non-conductive material (same material as the main body of the electrofusion joint 22) for inserting the connector insertion portion 18 of the electrode 8 of the connector 4. A plug-in portion (second terminal plug-in portion) 14 and a male electrode (second terminal electrode) 13 provided in the terminal plug-in portion 14 and capable of fitting with the electrode 8 are provided. Yes. The inner diameter of the terminal insertion part 14 has a predetermined dimension into which the connector insertion part 18 of the electrode 8 can be inserted.

  As shown in FIG. 5, when inserting into the terminal 51 of the electrofusion joint 21, the electrode 7 is selected, and the electrode 7 is inserted downward into the terminal 51. As a result, the male electrode 11 of the terminal 51 pushes up the electrode guard rod 10, the small diameter portion 10b of the electrode guard rod 10 closes the space in the electrode 8, the inner surface of the electrode 8 is not exposed, and a person or the like directly It is possible to prevent an electric shock by touching the electrode 8.

  As shown in FIG. 6, when inserting into the terminal 52 of the electrofusion joint 22, the electrode 8 is selected, and the electrode 8 is inserted downward into the terminal 52. As a result, the male electrode 13 of the terminal 52 pushes up the electrode guard rod 10, the large-diameter portion 10a of the electrode guard rod 10 closes the space in the electrode 7, the inner surface of the electrode 7 is not exposed, and a person etc. It is possible to prevent an electric shock by directly touching the electrode 7.

  Furthermore, foreign substances such as mud are less likely to enter the space by closing the space of the electrode (7 or 8) on the side where the electrode guard rod 10 is not inserted into the terminal 5. Thereby, an increase in contact resistance between the electrodes of the connector 4 and the terminal 5 is prevented. Further, rusting of the electrode surface due to moisture contained in mud or the like is prevented.

  As described above, since the electrode 7 and the electrode 8 are arranged vertically symmetrically in the connector 4, an operator or the like can easily select the electrode and can easily perform the insertion work into the terminal.

  Next, a mechanism for preventing erroneous insertion (including errors) according to the present invention will be described. As shown in FIG. 7, the connector of the present invention includes the first electrode 7 and the second electrode 8, and the inner diameter of the first electrode 7 is larger than the inner diameter of the second electrode 8. Therefore, the outer diameter of the male electrode 13 of the terminal 52 of the electric fusion joint (hereinafter referred to as “EF joint”) 22 of the company B connected to the second electrode 8 is that of the company A connected to the first electrode 7. The EF joint 21 has a smaller diameter than the outer diameter of the male electrode 11. Therefore, when the first electrode 7 is mistakenly inserted into the terminal 52 of the EF joint 22 of Company B, the inner diameter of the first electrode 7 is smaller than that of the male electrode 13 of the terminal 52 of the EF joint 22. Since the diameter is considerably larger than the outer diameter X (see FIG. 7), the male electrode 12 is fitted into the first electrode 7 while being in a so-called scaly state. In order to prevent this, the outer diameter Y (see FIG. 7) of the connector insertion portion 17 of the first electrode 7 is larger than the inner diameter Z (see FIG. 7) of the terminal insertion portion 14 of the EF joint 22 of B company. It is a diameter. Thereby, the connector insertion part 17 of the 1st electrode 7 and the terminal insertion part 14 of the EF joint 22 of B company contact | abut, and the connector insertion part 17 of the 1st electrode 7 is EF joint 22 of B company. As a result, the first electrode 7 is not joined to the terminal 52 of the EF joint 22 of B company.

  On the other hand, as shown in FIG. 8, when the second electrode 8 is mistakenly inserted into the terminal 51 of the EF joint 21 of company A, the terminal 51 of the EF joint 21 of company A is inserted into the second electrode 8. The male electrode 11 need not be inserted. Therefore, the inner diameter V (see FIG. 8) of the second electrode 8 is the outer diameter W (see FIG. 8) of the male electrode 11 of the terminal 51 of the EF joint 21 of company A. ) Is smaller than. As a result, the second electrode 8 abuts against the male electrode 11 of the terminal 51 of the EF joint 21 of Company A, and the male electrode 11 of the terminal 51 of the EF joint 21 cannot be inserted into the second electrode 8. As a result, the second electrode 8 is not connected to the terminal 51 of the EF joint 21 of company A.

  Next, an embodiment in which a thermoplastic resin pipe is fusion-bonded using an electric fusion joint using the present invention will be described.

FIG. 9 shows an outer surface of a resin pipe to be joined (hereinafter referred to as “pipe”) covered with an electric fusion joint (“EF joint”), and the pipe and the EF joint are fusion-bonded by energizing the EF joint. Thus, connecting the pipes: -14. It is explanatory drawing which shows the Example which consists of these processes. The present embodiment is a pipe joining operation common to the barcode method and the pressure detection method.
1. The surface of the fused part of the pipe 3 is cut.
2. The surface of the fused part of the pipe 3 is cleaned.
3. Clean the inner surface of the EF joint 2.
4). The pipe 3 is inserted into the EF joint 2.
5. The EF joint 2 and the pipe 3 are fixed with a clamp (fixing jig) (not shown).
6). A rubber cover (not shown) for preventing electric shock that has been put on the connector (hereinafter referred to as “connector”) 4 of the present invention is removed.
7). The terminal 5 of the EF joint 2 and the connector 4 of the power cable 6 are connected. The connection work process is shown in detail in the following (1) to (5).
(1) Select the electrode part of the connector according to the terminal shape of the EF joint selected from among multiple companies. For example, in this embodiment, the EF joint of company A is used, and the first electrode that matches the EF joint of company A is selected.
(2) In order to facilitate the selection, the electrode part of the connector (connector insertion part) is color-coded. This ensures that the electrodes are not mistaken.
(3) The connector insertion portion of the first electrode of the selected connector is inserted into the insertion portion of the terminal of the EF joint of Company A. Thereby, the male electrode of the terminal of the EF joint of company A is inserted into the first electrode, and the power cable is connected to the EF joint of company A. Since the first electrode and the second electrode of the connector are arranged symmetrically on both sides of the connector body, the energization control device for the electric fusion joint according to the present invention has an upper portion of the EF joint as shown in FIG. If the operator places the selected first electrode on the lower terminal of the connector and holds the connector, the first electrode can be easily inserted into the terminal of the lower EF joint.
(4) When the first electrode is inserted into the terminal of the lower EF joint, the electrode guard rod in the first electrode is pushed by the male electrode of the terminal of the EF joint of company A. What is the first electrode? It is pushed into the second electrode on the opposite side, the second electrode is closed, and the inner surface of the second electrode is not exposed. Thus, it is prevented that a person or the like touches the electrode directly to receive an electric shock. Furthermore, since the electrode guard rods block the electrode space on the non-connected side, foreign matter such as mud becomes difficult to enter, and increase in contact resistance between the electrode of the connector and the terminal is prevented, and contained in mud and the like. Rust on the electrode surface due to moisture is prevented.
(5) Since the energization control device for an electrofusion joint according to the present invention includes a mechanism for preventing erroneous insertion (including error), a connector that does not meet the standards and a terminal of an EF joint are not erroneously connected. .
8). The barcode label 16 is read by the barcode reader 15.
9. Press the fusion start button of the power supply control device 1.
10. Fusion (energization).
11. The connector 4 is removed from the joint terminal 5.
12 Attach a rubber cover to the connector 4.
13. Hold by cooling.
14 To the next EF joint fusion process.

DESCRIPTION OF SYMBOLS 1 Electric conduction control device 2 Electric fusion joint 21 Electric fusion joint 22 of company A Electric fusion joint 3 of company B Pipe 4 Connector 4a Connector main body 5 Terminal 51 Terminal 52 of electric fusion joint 21 of company A Electricity of company B Terminal 6 of fusion joint 22 Power cable 7 First electrode 8 Second electrode 9 Stopper 9a, 9b Hole 10 Electrode guard rod 10a Large diameter portion 10b of electrode guard rod Small diameter portion 10c of electrode guard rod Central portion 11 of electrode guard rod Male electrode (first terminal electrode)
12 Terminal insertion part (first terminal insertion part)
13 Male electrode (second terminal electrode)
14 Terminal insertion part (second terminal insertion part)
15 Bar code reader 16 Bar code label 17 Connector insertion part of the first electrode (first connector insertion part)
18 Second electrode connector insertion part (second connector insertion part)

Claims (3)

An electric conduction control device for an electric fusion joint used when joining an electric fusion joint and a resin pipe,
A connector, and a first connector insertion portion provided around the first electrode and a second connector insertion portion provided around the second electrode, disposed on the main body of the connector,
The first electrode and the second electrode are respectively a first terminal electrode provided in a first terminal insertion portion and a second terminal electrode provided in a second terminal insertion portion provided in the electric fusion joint. Can be mated with
The first connector insertion portion and the second connector insertion portion can be inserted into the first terminal insertion portion and the second terminal insertion portion, respectively.
The first connector insertion part cannot be inserted into the second terminal insertion part,
The second electrode cannot be fitted to the first terminal electrode;
Thereby, the first electrode and the second electrode can be connected only to the first terminal electrode and the second terminal electrode, respectively.
An electricity supply control device for an electric fusion joint characterized by the above.   The electromelting device according to claim 1, wherein the second terminal insertion portion is a concave insertion portion, and an inner diameter thereof is smaller than an outer diameter of the first connector insertion portion. Energization control device for joints.   The second electrode and the first terminal electrode are a female electrode and a male electrode, respectively, and an inner diameter of the second electrode is smaller than an outer diameter of the first terminal electrode. Item 3. An energization control device for an electric fusion joint according to item 1 or 2.

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