JP5360773B2 - Pipe cleaning method and pipe cleaning jig - Google Patents

Description

  The present invention relates to a pipe cleaning method and a pipe cleaning jig.

  In the reprocessing of spent fuel, the spent fuel sheared by a shearing machine is dissolved by heating while supplying nitric acid in a dissolution tank. Sludge generated as the spent fuel is dissolved is collected in the swarf basket of the dissolution tank or is removed by the clarification process along with the dissolution liquid. It will be deposited inside.

  Dissolution solution feeding in the dissolution tank is performed using a jet pump driven by steam, but the jet pump suction pipe disposed inside the dissolution tank may be narrowed or blocked by sludge.

  Therefore, in order to smoothly feed the solution, it is necessary to perform pipe cleaning for removing sludge adhering to the jet pump suction pipe.

  Cleaning of the jet pump suction pipe that feeds the dissolved liquid from the conventional dissolution tank that dissolves spent fuel is performed by freezing the solution in the pipe by freezing the discharge side pipe from the outside using a freezing device. After the stopper is generated, high-pressure water is injected from the steam supply system so that the sludge in the suction pipe that is narrowed or blocked by the sludge is physically removed.

  However, this cleaning method using a freezing device uses a large amount of water to generate a freezing plug, so that a large amount of radioactive waste liquid is generated and a large amount of radioactive waste liquid is generated. It is unsuitable.

  There is also a cleaning method that uses a wire-type cleaning machine to clean the inside of the pipe, but it is applicable to cleaning of the suction pipe of a jet pump that feeds the dissolved liquid from a spent fuel dissolution tank that is long and has many bends. It is difficult to do.

JP 2001-147296 A

  The present invention proposes a pipe cleaning method suitable for cleaning a jet pump suction pipe for feeding a solution in a dissolution tank for dissolving spent fuel, and a pipe cleaning jig suitable for carrying out the method. is there.

  In the pipe cleaning method of the present invention, the strainer of the jet pump that sucks the solution in the dissolution tank from the suction pipe connected to the inside of the dissolution tank and sends it to the delivery channel is removed from the strainer connection port to the suction pipe, Open the jet pump inspection port, insert a pipe cleaning jig from the jet pump inspection port instead of the removed strainer, and join the tip of the pipe cleaning jig cylinder to the strainer connection port in an airtight state. The suction pipe is cleaned by pumping a cleaning fluid through the cylindrical body to the suction pipe.

  Further, the pipe cleaning jig of the present invention has a double structure that is slidable in the axial direction, and the tip portion has a cylindrical shape in which a protruding portion in which the inner cylindrical body projects earlier than the outer cylindrical body is formed. And the outer cylinder is swelled so that the outer diameter is reduced by increasing the outer diameter by sliding the inner cylinder so as to shorten the projection amount of the projection. It is characterized by comprising an elastic body and a cleaning fluid channel provided in the inner cylinder and communicating between the proximal end and the distal end of the inner cylinder.

  According to the pipe cleaning method and the pipe cleaning jig suitable for carrying out the method of the present invention, the pipe cleaning jig is attached using the strainer mounting portion in the jet pump, and the suction pipe to the jet pump is easily made efficient. Can be cleaned.

The jet pump which sends the solution in the dissolution tank in a reprocessing facility is shown, (a) is a longitudinal front view, (b) is a right side view. It is a front view of the piping washing jig which is an Example of the present invention. The outer cylinder in the piping washing jig which is an Example of this invention is shown, and is a front view (a), a left side view (b), and a right side view (c). The lock nut in the pipe washing jig which is an Example of the present invention is shown, and is a front view (a) and a left side view (b). The stopper in the piping washing jig which is an Example of the present invention is shown, and is a front view (a), a left side view (b), and a right side view (c). The inner cylinder in the piping washing jig which is an Example of the present invention is shown, and is a front view (a), a left side view (b), and a right side view (c). The airtight elastic body in the piping washing jig which is an Example of this invention is shown, and is a front view (a), a left side view (b), and a right side view (c). It is a pipe cleaning system diagram using the pipe cleaning jig which is an example of the present invention. It is a piping washing work process figure which is an Example of this invention.

  The pipe cleaning jig of the present invention has a double structure that is slidable in the axial direction and has a cylindrical body in which a tip portion is formed with a protruding portion in which an inner cylindrical body projects earlier than an outer cylindrical body. An elastic body that is fitted on the outer periphery of the protruding portion and bulges the outer periphery so as to shrink in the axial direction and increase the outer diameter by sliding the inner cylinder so as to shorten the protruding amount of the protruding portion. And a cleaning fluid channel provided in the inner cylinder and communicating between the proximal end and the distal end of the inner cylinder. The pipe cleaning using this pipe cleaning jig is performed by sucking the solution in the dissolution tank from the suction pipe connected to the inside of the dissolution tank and sending the strainer of the jet pump to the suction flow path to the suction pipe. Remove from the strainer connection port, open the jet pump inspection port, insert a pipe cleaning jig from the jet pump inspection port instead of the removed strainer, and use the tip of the pipe cleaning jig cylinder as the strainer connection port. It joins in an airtight state and the cleaning fluid is pumped through the cylindrical body to the suction pipe to clean the inside of the suction pipe.

  A jet pump for feeding a solution in a dissolution tank in a reprocessing facility will be described with reference to FIG.

  A jet pump 1 that is a power for liquid feeding connects a strainer 1d from a pump chamber 1b formed by a pump casing 1a to a strainer connection port 1c connected to a suction pipe 2, and jets a jet fluid toward a delivery channel 1e. A jet nozzle 1f is provided. When jet fluid (steam) is ejected from the jet nozzle 1f, the fluid in the pump chamber 1b is also drawn and sent together to the delivery channel 1e. When the fluid in the pump chamber 1b is delivered, the pressure in the pump chamber 1b decreases, so the solution in the suction pipe 2 is sucked out through the strainer 1d and flows into the pump chamber 1b.

  Then, the solution that has flowed into the pump chamber 1b is sent to the delivery channel 1e in the same manner, and the solution is delivered.

  Although not shown in the drawings, the strainer 1d is a cylindrical body having a front end opened, a rear end sealed, and a filtration window formed in an intermediate region, and the rear end is engaged with the pump casing 1a. Provide with pawls.

  The strainer 1d is connected to the strainer connection port 1c of the jet pump 1 by forming a jet pump inspection port 1g in the pump casing 1a opposite to the strainer connection port 1c, and inserting the strainer 1d through the jet pump inspection port 1g. Is connected to the strainer connection port 1c and the engaging claw at the rear end is engaged with the pump casing 1a to fix the opening of the strainer 1d so as to communicate with the suction pipe 2.

  The strainer 1d is removed from the jet pump 1 by releasing the locking claw of the strainer 1d from the pump casing 1a and pulling it out from the jet pump inspection port 1g.

  The suction pipe 2 connected to the jet pump 1 is cleaned by removing the strainer 1d from the jet pump inspection port 1g and replacing the removed strainer 1d with the tubular pipe cleaning jig 3 from the jet pump inspection port 1g. Is inserted, the tip of the pipe cleaning jig 3 is inserted into the strainer connection port 1c and joined in an airtight state, and the cleaning fluid is pumped to the suction pipe 2 through the cylindrical body.

  As shown in FIG. 2, the pipe cleaning jig 3 has a double structure that is relatively slidable in the axial direction, and the tip portion projects from the inner cylinder 31 before the outer cylinder 32. And the inner cylinder 31 relative to the outer cylinder 32 so as to be fitted on the outer periphery of the protrusion 31a of the inner cylinder 31 and to shorten the protruding amount of the protrusion 31a. And an airtight elastic body 33 that bulges its outer circumference so as to shrink in the axial direction and increase its outer diameter, and a base end portion and a distal end of the inner cylinder body 31 provided in the inner cylinder body 31. A cleaning fluid flow path 31b that penetrates the part and opens at the tip is provided.

  A space between the outer cylinder 32 and the inner cylinder 31 is sealed by a plurality of O-rings 34 so as to be slidable.

  As shown in FIG. 3, the outer cylinder 32 is inserted at the outer periphery of the intermediate portion thereof, similarly to the base end portion of the strainer 1 d, so that the tip of the protruding portion 31 a of the inner cylinder 31 is inserted into the strainer connection port 1 c. A locking claw 32a that is engaged so as to be locked to the pump casing 1a in the joined state is formed. Further, at the base end portion, the outer cylinder 32 is rotated to engage the engaging claw 32a with the pump casing 1a, and the inner cylinder 31 is screwed into the lever 32b to engage the inner cylinder 31 with the outer cylinder. A lock nut 35 is provided for sliding forward and backward relative to the body 32. The lock nut 35 includes a flange 35b on the end surface of the screw body 35a, and is attached to a stopper 37 fixed to the base end surface of the outer cylindrical body 32 by a screw 36 so as to rotatably engage the flange 35b. . FIG. 4 shows the lock nut 35, and FIG. 5 shows the stopper 37.

As shown in FIG. 6, the inner cylinder 31 has a base end projecting from the outer cylinder 32, a thread groove 31c formed on the outer periphery thereof, and a lock nut 35 screwed into the thread groove 31c. After the lock nut 35 is brought into contact with the base end of the outer cylinder 32 by screwing, the inner cylinder 31 is slid so as to be pulled out in the base end direction and is fitted to the protruding portion 31a of the inner cylinder 31. The airtight elastic body 33 is compressed in the axial direction and expanded in the outer diameter direction, and is pressed against the inner wall surface of the strainer connection port 1c. A flange 31a ₁ for preventing the airtight elastic body 33 from coming off is formed at the tip of the protruding portion 31a. FIG. 7 shows the airtight elastic body 33.

  In addition, a cleaning pipe connection terminal 31 d for selectively connecting a pipe that supplies the cleaning fluid is formed in the cleaning fluid channel 31 b that opens to the base end of the inner cylinder 31.

As shown in FIG. 8, the cleaning fluid supply system connected to the cleaning pipe connection terminal 31d includes a pressurization system, a reagent supply system, and a high-pressure water supply system. The pressurization system is a system that supplies pure water by the hand pump 41. The reagent supply system is a system in which a NaOH solution, an HNO ₃ solution, and pure water stored in the pressure feed tank 51 are pressurized by the compressor 52 and supplied. The high-pressure water supply system is a system that supplies pure water accommodated in the tank 61 after being pressurized to a high-pressure state by the high-pressure water supply device 62. The reagent in the cleaning fluid is selected on the assumption that the sludge accumulated in the suction pipe 2 is zirconium molybdate, and is set according to the type of the deposit.

  A cleaning operation process of the suction pipe 2 using the pipe cleaning jig 3 will be described with reference to FIG.

Step S1
The fact that the flow rate of the jet pump 1 has decreased to a predetermined value is confirmed by the liquid level drop rate of the liquid level gauge of the liquid source storage tank. In addition, the solution is continuously fed by the jet pump, or is fed by a jet pump of another system, and the entire amount is fed.

Step S2
After confirming that the liquid amount in the liquid-source storage tank is not more than a predetermined amount, pure water is supplied from the jet nozzle 1f of the jet pump 1 into the pump chamber 1b. Thereafter, the jet pump 1 is started and the inside of the delivery system is steam blown, and then the jet pump 1 is stopped.

Step S3
The strainer 1d of the jet pump 1 is removed, and a pipe cleaning jig 3 is attached instead. Then, pure water is supplied from the pressure feed tank 51 to release air from the system including the inside of the suction pipe 2.

Step S4
The lock nut 35 in the pipe cleaning jig 3 is screwed to expand the airtight elastic body 33 at the tip so that the pipe cleaning jig 3 and the suction pipe 2 can be kept airtight against high pressure. Then, the suction pipe 2 is pressurized by the hand pump 41 while monitoring a pressure gauge (not shown), and the pressure drop time after the pressurization is measured.

Step S5
Measure (determine) the pressure drop time or maximum pressure pressure and branch the cleaning process. Specifically, it is measured whether the pressure drop time exceeds 1 second or the pressurization pressure is 0.05 MPa or more.

Step S6
If NO, branch to high pressure water cleaning. In this cleaning, a high pressure water supply system is connected to the pipe cleaning jig 3 to supply high pressure water from the tank 61 into the suction pipe 2. Then, the lock nut 35 of the pipe cleaning jig 3 is loosened to restore the airtight elastic body 33 to a small diameter, the pipe cleaning jig 3 is extracted from the jet pump inspection port 1g, and the strainer 1d is attached.

Step S7
The jet pump 1 is activated to measure the liquid feeding amount. If the liquid feeding amount has recovered to the predetermined amount, the cleaning is terminated, and if not, the process returns to step S1.

Step S8
If YES in step S5, the process branches to cleaning using a reagent. In this cleaning, the lock nut 35 of the pipe cleaning jig 3 is loosened to restore the airtight elastic body 33 to a small diameter, thereby releasing the airtightness in the suction pipe 2 and starting the jet pump 1 to discharge the solution in the system. To do. Then, NaOH is supplied from the pressure tank 51 to perform liquid replacement and air venting in the system including the inside of the suction pipe 2. Thereafter, the lock nut 35 in the pipe cleaning jig 3 is screwed to expand the airtight elastic body 33 at the tip so that the pipe cleaning jig 3 and the suction pipe 2 can be kept airtight against high pressure. To do. NaOH is supplied from the pressure tank 51 (pressure 0.4 MPa), and the inside of the suction pipe 2 is pressurized by the hand pump 41 while monitoring a pressure gauge (not shown), and the pressure drop time is measured.

Step S9
By loosening the lock nut 35 of the pipe cleaning jig 3 and restoring the airtight elastic body 33 to a small diameter, the airtightness in the suction pipe 2 is released, the jet pump 1 is activated, and the solution in the system is discharged. Then, HNO ₃ is supplied from the pressure feed tank 51 to perform liquid replacement and air venting in the system including the inside of the suction pipe 2. Thereafter, the lock nut 35 in the pipe cleaning jig 3 is screwed to expand the airtight elastic body 33 at the tip so that the pipe cleaning jig 3 and the suction pipe 2 can be kept airtight against high pressure. . HNO ₃ is supplied from the pressure tank 51 (pressure 0.4 MPa), and the suction pipe 2 is pressurized by the hand pump 41 while monitoring a pressure gauge (not shown), and the pressure drop time is measured. Then, the process returns to step S5.

DESCRIPTION OF SYMBOLS 1 ... Jet pump, 1a ... Pump casing, 1b ... Pump chamber, 1c ... Strainer connection port, 1d ... Strainer, 1e ... Delivery flow path, 1f ... Jet nozzle, 1g ... Jet pump inspection port, 2 ... Suction piping, 3 ... Pipe cleaning jig, 31 ... inner cylinder, 31a ... protrusion, 31a ₁ ... 鍔, 31b ... cleaning fluid flow path, 31c ... screw groove, 31d ... cleaning pipe connection terminal, 32 ... outer cylinder, 33 ... hermetic elasticity Body, 34 ... O-ring, 35 ... Lock nut, 35a ... Screw part, 35b ... 鍔, 41 ... Hand pump, 51 ... Pressure tank, 61 ... Tank.

Claims (2)

  Remove the strainer of the jet pump that sucks the solution in the dissolution tank from the suction pipe connected to the inside of the dissolution tank and sends it to the delivery flow path, and removes it from the strainer connection port to the suction pipe. Insert the pipe cleaning jig from the inspection port, join the tip of the pipe cleaning jig cylinder to the strainer connection port in an airtight state, and pump the cleaning fluid through the cylindrical body to the suction pipe. A piping cleaning method characterized by performing cleaning.   A double structure that is relatively slidable in the axial direction, and the distal end portion is fitted to a cylindrical body in which an inner cylindrical body forms a protruding portion that protrudes ahead of an outer cylindrical body, and the outer periphery of the protruding portion. And an elastic body that swells the outer periphery so as to shrink in the axial direction and increase the outer diameter by sliding the inner cylinder so as to shorten the protruding amount of the protrusion, and provided in the inner cylinder. A pipe cleaning jig comprising a cleaning fluid channel that communicates the base end portion and the tip end portion of the inner cylindrical body.

Images