JP2018031403A - Rotary joint - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the leakage of a liquid medium from a seal material.SOLUTION: A rotary joint includes: a cylindrical rotor 1 coaxially attached with a rotary shaft of a rotator at one end portion 1A, and rotated around an axis O; and a casing 11 arranged on an outer periphery of the rotor 1. In the inside of the rotor 1, a flow path 5 in which a liquid medium opening at the one end portion 1A of the rotor 1 and a liquid medium discharged from the rotator circulates; and a discharge chamber 8 which communicates to the other end portion of the flow path 5 and is formed with a discharge port 8A discharging the liquid medium so as to open to an outer peripheral portion of the rotor 1, are provided. The casing 11 is formed with a communication chamber 16 communicating to the discharge port 8A. Between the rotor 1 and the casing 11, a seal material 17B is arranged at a position separated in an axis O direction from the discharge port 8A, and between the discharge port 8A and the seal material 17B in the axis O direction, a shielding member 8B projecting out from the outer peripheral portion of the rotor 1 is provided.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a rotary joint used for supplying or discharging a heat medium such as high-temperature steam to a rotating body such as a steam tube dryer or a heating roll.

  As such a rotary joint, for example, Patent Document 1 discloses a casing whose one end is opened, and a tubular rotor which is rotatably supported by a pair of bearings in this casing and has one end coaxially attached to a rotating body. , A spacer mounted so as to provide a gap between the pair of bearings, an inner tube provided in the casing so as to penetrate the inside of the rotor, and a special carbon seal that seals the inside of the casing and the inside of the rotor There has been proposed a ring including a ring and a seal member provided between the bearing on the other end side and the seal ring so as to cover the periphery of the rotor without a gap. In the rotary joint described in Patent Document 1, a heat medium is supplied to the inside of the rotating body through the inner pipe, and the heat medium used for heating in the rotating body is discharged between the inner pipe and the rotor.

JP 2007-120694 A

  By the way, in the rotary joint described in Patent Document 1, the seal member is disposed after a pair of bearings and a spacer are arranged from one end of the rotor attached to the rotating body toward the other end. It is provided so as to cover the periphery of the rotor, and on the other end side than the seal member, the seal ring is merely pressed in the axial direction against the seat ring fitted to the other end surface of the rotor. is there.

  However, for example, in a rotary joint in a steam tube dryer or a heating roll, since the axis of the rotor is usually oriented in the lateral direction, the seal ring on the other end side of the seal member is thus axially connected to the rotor. If only the rotor is pressed, especially when the length of the rotor from the bearing on the other end side to the seal ring is long, uneven wear occurs in which the lower portion of the seal member is greatly worn by the weight of the rotor. easy. When such uneven wear becomes significant, leakage of an object to be sealed by the seal member (in the rotary joint described in Patent Document 1, grease supplied to the pair of bearings) occurs.

  Therefore, the inventors of the present invention previously disclosed in Japanese Patent Application No. 2015-101755 that, in order to solve such a problem, a cylinder whose one end is attached coaxially with the rotating shaft of the rotating body and rotated around the axis. And a casing disposed on the outer periphery of the rotor, and a plurality of sets of sealing materials for sealing between the rotor and the casing, and the rotor between the rotor and the casing. The same number of bearing members as the number of sets of the sealing materials that are rotatably supported by the casing are alternately interposed in the order of the sealing materials and the bearing members from one end of the rotor to the other end. Has proposed a rotary joint.

  In such a rotary joint, between the rotor and the casing, a plurality of sets of sealing materials that seal between the rotor and the casing, and a plurality of sealing materials that support the rotor rotatably on the casing are the same number. Since the bearing member is alternately interposed in the order of the sealing material and the bearing member from one end of the rotor to the other end, the next to the one end of the rotor that is attached to and supported by the rotating body In the sealing material interposed on the other end side, both sides in the axial direction of the rotor are supported by the bearing member positioned on the other end side and the one end portion.

  Further, in the sealing material interposed on the other end side of the sealing material next to the one end portion of the rotor, the rotor is supported by the two bearing members on both sides in the axial direction. Even with the rotary joint that is directed, it is possible to avoid the occurrence of uneven wear in the lower part of the sealing material due to the weight of the rotor. Therefore, it is possible to prevent the uneven wear from increasing and the leakage of the target object to be sealed by the sealing material, and to perform processing such as heating and drying with a stable rotating body over a long period of time. be able to.

  By the way, when the rotating body is a steam tube dryer or a heating roll, normally high-temperature water vapor is supplied as a heating medium, and after the heated object is heated in the rotating body, it is discharged as a liquid medium such as high-temperature water. In such a steam tube dryer and a heating roll, the discharge amount of the discharged liquid medium is not constant but pulsates. However, in the rotary joint described in the above Japanese Patent Application No. 2015-101755, a seal such as a gland packing is also provided at a position away from the discharge port of the discharge chamber in the rotor from which the liquid medium is discharged to the other end side in the axial direction. In the rotary joint in which the material is interposed between the rotor and the casing, and the axis line is oriented in the horizontal direction as described above, the liquid medium passes through the discharge port opened on the lower side of the rotating rotor, and the outer peripheral surface of the rotor May reach the sealing material and cause leakage.

  The present invention has been made under such a background. Even if a sealing material is disposed between the rotor and the casing at a position away from the discharge port in the axial direction, the liquid from the sealing material can be obtained. An object of the present invention is to provide a rotary joint capable of preventing the leakage of a medium.

  In order to solve the above-described problems and achieve such an object, the present invention provides a cylindrical rotor having one end attached coaxially to a rotating shaft of a rotating body and rotated around the axis, A casing disposed on the outer periphery, and in the rotor, a flow path that opens at one end in the axial direction of the rotor and through which the liquid medium discharged from the rotating body circulates, and the flow path A discharge chamber formed so that a discharge port through which the liquid medium is discharged in communication with the other end portion of the rotor opens to the outer peripheral portion of the rotor is provided, and the casing communicates with the discharge port. A communication chamber is formed, and a sealing material that seals between the rotor and the casing is disposed between the rotor and the casing at a position away from the discharge port in the axial direction. Axial direction Between the outlet and the sealing material of the rotor, wherein the blocking member protruding from the outer peripheral portion of the rotor is provided.

  In the rotary joint configured as described above, a shielding member that protrudes from the outer periphery of the rotor is provided between the discharge port of the discharge chamber that opens to the outer periphery of the rotor and the sealing material. Even if the liquid medium is transmitted in the axial direction along the outer peripheral surface of the rotor from the discharge port opened to the side, it can be prevented by the shielding member from reaching the sealing material at a position separated in the axial direction. For this reason, it can prevent that a liquid medium leaks from a sealing material, and can perform processing, such as a heating of the to-be-heated material stabilized in a steam tube dryer or a heating roll.

  Here, the shielding member may be, for example, an annular plate-shaped plate wall member that protrudes between the discharge port and the sealing material on the entire outer periphery of the rotor. By using a cylindrical member that protrudes to the side, even if a large amount of liquid medium is discharged, it can be prevented from being scattered and scattered, and the liquid medium can reach the sealing material due to such splashing. Can be prevented.

  On the other hand, it is possible to secure a long flow path by projecting the other end of the flow path in the axial direction toward the other end in the axial direction in the discharge chamber. By absorbing the pulsation, the discharge amount of the liquid medium discharged into the communication chamber of the casing can be made uniform, and leakage from the sealing material due to the liquid medium remaining in the discharge chamber can be prevented. In addition, since it takes a long time for the liquid medium to reach the communication chamber and the flow velocity of the liquid medium flowing into the communication chamber can be suppressed, the liquid medium that has flowed into the communication chamber at a high speed is scattered and reaches the sealing material. It is possible to prevent leakage.

  In particular, in this case, the other end portion of the flow path in the axial direction is protruded from the edge of the discharge port on the other end side in the axial direction in the discharge chamber. Since the liquid medium once discharged from the end to the other end side than the discharge port returns to the one end side in the axial direction and is discharged from the discharge port to the communication chamber, the amount of discharge of the liquid medium is further increased. Uniformity can be achieved and the time to reach the communication chamber can be further extended, and leakage due to reaching the sealing material can be reliably prevented.

  As described above, according to the present invention, even if the sealing material is disposed between the rotor and the casing in the axial direction from the discharge port from the discharge chamber to the communication chamber, the liquid is applied to the seal material. It is possible to prevent leakage due to the arrival of the medium, and it is possible to achieve stable processing in the rotating body.

It is a perspective view which shows one Embodiment of this invention. It is sectional drawing along the axis line of the rotor of embodiment shown in FIG. It is sectional drawing along the axis line of the rotor of the modification of embodiment shown in FIG.

  1 and 2 show an embodiment of the present invention. As for the rotary joint of this embodiment, the main members are formed with metal materials, such as steel materials, and among these, rotor 1 is centering on axis O of a fixed outside diameter except for an attaching part and a flange part mentioned below. It has a cylindrical shape. Further, one end 1A of the rotor 1 in the direction of the axis O (the lower left portion in FIG. 1 and the left portion in FIG. 2) has a cylindrical inner diameter that is one step smaller than the rotor 1 centered on the axis O. The pipe 2 is inserted and supported by a support plate 3 extending in the radial direction along a plane including the axis O, and the space between the rotor 1 and the inner pipe 2 and the space in the inner pipe 2 are Opened at one end of the rotor 1.

  Further, an annular plate-like attachment portion 4 is provided on the outer periphery of the one end portion 1A of the rotor 1, and the end portion 1A is not illustrated via the attachment portion 4, and a dryer body of a steam tube dryer or a roll of a heating roll. By being mounted coaxially with the rotation axis of a rotating body such as a main body, the rotor 1 is connected to the rotating body and rotated integrally around the axis O. And the space in the inner tube 2 of the rotor 1 is connected to the heat medium discharge side of this rotating body and serves as a discharge flow path 5 which is a flow path in the present embodiment of the heat medium (liquid medium), while the rotor A space between 1 and the inner pipe 2 is connected to the heat medium supply side of the rotating body to serve as a heat medium supply flow path 6.

  In addition, in one end 1A of the rotor 1, on the other end 1B side (upper right side in FIG. 1 and right side in FIG. 2) of the rotor 1 opposite to the one end 1A in the axis O direction, the supply flow path 6 is It is sealed by the first partition wall 7A, and the discharge channel 5 and the supply channel 6 are hermetically isolated. Furthermore, in the present embodiment, the inner tube 2 protrudes from the first partition 7A toward the other end 1B. A second partition wall 7B is provided at a position spaced from the first partition wall 7A in the rotor 1 toward the other end 1B, and the first and second partition walls 7A and 7B in the rotor 1 are provided. The portion between is a heat medium discharge chamber 8 communicating with the discharge flow path 5.

  On the other hand, a portion closer to the other end 1B than the second partition wall 7B is a heat radiating chamber 9 that is isolated from the discharge chamber 8 and the discharge flow path 5. The heat radiation chamber 9 has a circular opening 9A on the other end face of the rotor 1 and opens to the outside, that is, is open to the atmosphere. In the rotor 1, a plurality of through holes extending perpendicularly to the axis O are formed at positions of the supply flow path 6 and the discharge chamber 8 at intervals in the circumferential direction. The outlet is 8A. Here, in the present embodiment, the inner tube 2 protruding from the first partition wall 7A as described above protrudes toward the other end side from the edge portion on the other end side in the axis O direction of the discharge port 8A. ing.

  In the present embodiment, a flange portion 10 is provided on the other end portion 1 </ b> B side of the rotor 1 so as to project to the outer peripheral side in the radial direction with respect to the axis O. The flange portion 10 is formed in an annular plate shape having a larger outer diameter than the rotor 1 having an opening portion 10A having the same diameter as the opening portion 9A of the heat radiation chamber 9 at the center thereof. It is arranged at the other end of the rotor 1 with the axis O as the center perpendicular to the axis O.

  On the outer periphery of the rotor 1, a casing 11 that is fixed in a non-rotating manner with respect to the rotor 1 that is rotated around the axis O as described above is disposed, and the rotor 1 is rotatable in the casing 11. Supported. The casing 11 has a cylindrical shape with an axis O having an inner diameter larger than the outer diameter of the rotor 1 as the center, and an axis having an inner diameter into which the rotor 1 can be inserted at one end and the other end in the direction of the axis O. First and second partition walls 12 and 13 perpendicular to the axis O having through holes 12A and 13A centering on O are provided, and between these first and second partition walls 12 and 13, A third partition wall 14 having a through hole 14A slightly larger than the through holes 12A and 13A is provided. A casing flange portion 11 </ b> A is provided on the outer periphery of the other end portion of the casing 11 so as to project to the outer peripheral side.

  Among these, the space on the one end side in the direction of the axis O between the first and third partition walls 12 and 14 is a supply communication chamber 15 that communicates with the supply flow path 6 via the supply port 6A of the rotor 1. A supply pipe 15 </ b> A that communicates with the supply communication chamber 15 and is connected to a heat medium supply path to the rotary joint is provided on the outer periphery of the casing 11 at the position of the supply communication chamber 15. Further, the space on the other end side in the axis O direction between the second and third partition walls 13 and 14 communicates with the discharge chamber 8 and the discharge flow path 5 via the discharge port 8A of the rotor 1. A discharge communication chamber 16 that is a communication chamber in the discharge communication chamber 16, and a discharge pipe that communicates with the discharge communication chamber 16 and is connected to a heat medium discharge path from the rotary joint at the outer periphery of the casing 11 at the position of the discharge communication chamber 16. 16A is provided.

  Each of the supply pipe 15A and the discharge pipe 16A has a center line disposed at the same position as the center line of the supply port 6A and the discharge port 8A in the direction of the axis O, and the inner diameter thereof is the supply port 6A and the discharge port. It is larger than the inner diameter of 8A. Further, the inner diameter of the supply pipe 15A is made larger than the inner diameter of the discharge pipe 16A, and the supply pipe 15A and the discharge pipe 16A are provided on the opposite sides in the circumferential direction of the casing 11.

  The first and second partition walls 12 and 13 of the casing 11 have a plurality of sets (two sets) of first and second seals between the through holes 12A and 13A and the outer peripheral surface of the rotor 1. Materials 17A and 17B are interposed. Accordingly, among these, the second sealing material 17B is disposed at a position away from the discharge port 8A toward the other end side in the axis O direction. These sealing materials 17A and 17B are gland packings in the present embodiment, and are so-called braided gland packings, in particular, having a square cross section and made of braided cords of expanded graphite and carbon fibers.

  Here, in the present embodiment, the seal mounting portions 12B and 13B are provided so that the through holes 12A and 13A are enlarged by one step on the outer side in the axis O direction of the first and second partition walls 12 and 13, respectively. A plurality of braided gland packings as described above are packed in the direction of the axis O in a space (stuffing box) formed between the inner peripheral surface of these seal mounting portions 12B and 13B and the outer peripheral surface of the rotor 1. After the first and second seal members 17A and 17B each having a set are configured, the heat medium is sealed by being tightened by the packing presser 18 having an annular shape with an L-shaped cross section.

  Further, in the present embodiment, between the through hole 14A of the third partition wall 14 and the outer peripheral surface of the rotor 1, one of a plurality of bearing members equal in number (two) to the number of sets of the sealing material 17 is provided. As a matter of course, a first bearing member 19 is interposed. The first bearing member 19 is a sliding bearing (bush) in this embodiment, and is an oil-impregnated bearing in which a base material such as cast iron having an L shape in cross section is impregnated with a lubricant (lubricating oil). The rotor 1 is fitted between the inner peripheral surface of the through hole 14A and the outer peripheral surface of the rotor 1 and attached to the third partition wall 14 by bolting or the like, and is supported by the rotating rotor 1 slidingly contacting the inner peripheral surface. Is done.

  On the other hand, the other end of the casing 11 is provided with an extending portion 20 that extends in a cylindrical shape at an interval on the outer peripheral side of the rotor 1. The extending portion 20 includes a barrel portion 20A whose outer shape centering on the axis O is cylindrical, and an annular plate-like extending flange portion projecting outward from both ends in the axis O direction of the barrel portion 20A. 20B, 20C, and an extension flange portion 20B on one end side in the direction of the axis O is fixed to the casing flange portion 11A and attached to the other end of the casing 11. The seal attachment portion 13B, the second seal material 17B, and the packing retainer 18 on the second partition wall 13 side of the casing 11 are disposed on the inner side of the body portion 20A, and extend on the other end side of the extension portion 20. The flange portion 20C is opposed to the flange portion 10 of the rotor 1 with an interval in the direction of the axis O.

  A second bearing member 21 is interposed between the extended flange portion 20C and the flange portion 10 of the rotor 1 as another one of the plurality of bearing members in the present embodiment. In the present embodiment, the second bearing member 21 is a slewing bearing (rolling bearing), that is, an inner ring attached to one of the flange portion 10 and the extended flange portion 20C, and an outer ring attached to the other. For example, a ball bearing including a rolling element such as a ball interposed between inner and outer rings so as to be able to roll, and a lubricant such as grease is sealed between inner and outer rings on which the rolling element rolls.

  Such a second bearing member 21 has a casing 10 in the radial direction with respect to the axis O as shown in FIG. 2, with the inner and outer rings being attached to the outer peripheral portions of the flange portion 10 and the extended flange portion 20C. 11 in the outer peripheral side of the supply and discharge communication chambers 15 and 16, and in the direction of the axis O, in the annular direction centering on the axis O, closer to the other end 1B side of the rotor 1 than the second sealing material 17B. It is arranged.

  Therefore, in this embodiment, a plurality of sets (two sets) of the first and second sealing materials 17A and 17B that seal between the rotor 1 and the casing 11, and the rotor 1 that rotatably supports the casing 1 on the casing 11. 1, the same number (two) of first and second bearing members 19 and 21 as the number of sets of the second seal members 17A and 17B are connected from the one end 1A to the other end 1B of the rotor 1 attached to the rotating body. The first sealing material 17A, the first bearing member 19, the second sealing material 17B, and the second bearing member 21 are alternately inserted in this order toward the side.

  Of these, the second bearing member 21 located on the other end side in the direction of the axis O includes a discharge flow path 5, a supply flow path 6, and a discharge chamber 8 of the rotor 1, which are flow paths for the heat medium. By disposing the heat radiating chamber 9 and the extension portion 20 from the supply communication chamber 15 and the discharge communication chamber 16 of the casing 11 that are communication chambers, the distant portion 1B is disposed away from the other end portion 1B in the axis O direction. In addition, by providing the flange portion 10 and the extended flange portion 20C, the flange portion 10 and the extended flange portion 20C are disposed at positions away from the outer peripheral side in the radial direction with respect to the axis O.

  Further, the extended portion 20 is provided with a fin 22 that protrudes radially outward with respect to the axis O, and an opening 23 that penetrates the extended portion 20 in the radial direction with respect to the axis O. In the present embodiment, a plurality (four) of fins 22 are provided at equal intervals in the circumferential direction on the outer periphery of the trunk portion 20 </ b> A of the extending portion 20. 4) openings 23 are provided at equal intervals in the circumferential direction.

  The fin 22 extends from the outer periphery of the trunk portion 20A of the extending portion 20 along the plane including the axis O with a constant protrusion amount in the radial direction, and extends between the extending flange portions 20B and 20C in the axis O direction. It is formed in a flat plate shape that extends. Further, the opening 23 penetrates in the radial direction so as to cut out the body portion 20A of the extending portion 20 substantially entirely with a small gap between the extending flange portions 20B, 20C and the fins 22. Therefore, each opening 23 is formed in a rectangular shape when viewed from the outer peripheral side.

  Further, in the present embodiment, the rotor is disposed between the discharge port 8A of the rotor 1 and the second sealing material 17B disposed at a position away from the discharge port 8A on the other end side in the axis O direction. A shielding member 8 </ b> B protruding from the outer peripheral portion of 1 is provided. In the present embodiment, the shielding member 8B is a cylindrical member such as a short circular tube that protrudes from the periphery of each of the plurality of discharge ports 8A to the outer peripheral side, and is joined by, for example, screwing or welding, etc. The outer peripheral end is spaced from the inner peripheral surface of the discharge communication chamber 16.

  In such a rotary joint of this embodiment, the heat medium such as high-temperature steam supplied from the supply pipe 15A to the supply communication chamber 15 of the casing 11 is supplied to the rotor 1 rotated around the axis O as described above. The product passes through the supply channel 6 from the opening 6A, and is supplied to a heating tube on the heat medium supply side of a rotating body such as a dryer main body rotated by a steam tube dryer, for example, and used for heating and drying the object to be processed. In addition, the heat medium used for heating and drying the object to be processed in this way is aggregated to become a liquid medium such as high-temperature water and discharged from the heat medium discharge side of the rotor to the discharge flow path 5 of the rotor 1. The discharge chamber 8 passes through the discharge port 8A and the shielding member 8B, and is discharged through the discharge communication chamber 16 and the discharge pipe 16A.

  In the rotary joint configured as described above, the discharge port 8A for the heat medium (liquid medium) that opens to the outer peripheral portion of the rotor 1 and the second seal disposed at a position away from the discharge port 8A in the axis O direction. Since the shielding member 8B that protrudes from the outer peripheral portion of the rotor 1 is provided between the material 17B, the liquid medium passes through the outer peripheral surface of the rotor 1 in the direction of the axis O from the discharge port 8A that opens on the lower side of the rotor 1. Even if it is transmitted, it can be blocked by the shielding member 8B from reaching the second sealing material 17B disposed at a position separated in the direction of the axis O. For this reason, it is possible to prevent the liquid medium from leaking from the second sealing material 17B, and it is possible to stably perform the processing such as heating of the heated object in the steam tube dryer or the heating roll.

  In the present embodiment, a cylindrical member such as a circular tube protruding from the periphery of the discharge port 8A to the outer peripheral side of the rotor 1 is provided as the shielding member 8B. In this respect, if the gap between the discharge port 8A and the second seal material 17B can be shielded, for example, a circle protruding between the discharge port 8A and the second seal material 17B on the entire outer periphery of the rotor 1. An annular plate-like plate wall member or an annular member having an L-shaped cross section with a turn bent toward one end in the axis O direction on the outer periphery of such a plate wall member may be used. By using the shaped member, even if a large amount of liquid medium is discharged from the discharge port 8A, it can be prevented that the liquid medium is scattered and splashed in the discharge communication chamber 16. It can also be prevented that the sealing material 17B is reached.

  On the other hand, in the present embodiment, the other end portion in the axis O direction of the inner tube 2 inserted into the rotor 1 protrudes from the first partition 7A toward the other end side in the axis O direction in the discharge chamber 8, Accordingly, the discharge channel 5 also protrudes toward the other end of the discharge chamber 8 in the axis O direction. Therefore, by increasing the length of the discharge flow path 5, the pulsation of the discharge amount of the liquid medium can be absorbed and uniformed, so that the discharge communication chamber 16 is discharged by discharging a large amount of the liquid medium. It is also possible to prevent a situation in which leakage occurs due to staying in the second seal material 17B. Further, since the discharge flow path 5 becomes longer in this way, it is possible to secure a long time until the liquid medium reaches the discharge communication chamber 16 and to suppress the inflow speed to the discharge communication chamber 16, and to discharge at a high speed. It is also possible to prevent the liquid medium that has flowed into the air from reaching the second sealing material 17B by splashing.

  Further, in the present embodiment, the other end portion of the discharge channel 5 thus protruding into the discharge chamber 8 protrudes from the edge of the discharge port 8A in the discharge chamber 8 on the other end side in the axis O direction. Therefore, the liquid medium discharged from the other end portion of the discharge flow path 5 is discharged after passing through the discharge flow path 5 once to the other end side in the direction of the axis O from the discharge port 8A. After returning to the one end side in the O direction, it is discharged from the discharge port 8A. Therefore, the discharge amount of the liquid medium can be further uniformed during that time, and the arrival time to the discharge communication chamber 16 can be made longer, and leakage due to the arrival at the second sealing material 17B can be prevented more reliably.

  On the other hand, in the rotary joint of the present embodiment, the through holes 12A and 13A of the first and second partition walls 12 and 13 of the rotor 1 and the casing 11 and the rotary joint described in Japanese Patent Application No. 2015-101755, The first and second seal members 17A and 17B for sealing between the first and second bearing members 19 and 21 for rotatably supporting the rotor 1 on the casing 11 are provided from one end 1A of the rotor 1. It is alternately inserted toward the other end 1B side. Accordingly, the rotor 1 is supported by the rotating body and the first bearing member 19 on both sides of the first sealing material 17A in the axis O direction, and the rotor 1 is first on both sides of the second sealing material 17B in the axis O direction. The second bearing members 19 and 21 are supported.

  For this reason, when the axis O of the rotor 1 is oriented in the horizontal direction, such as a steam tube dryer or a rotary joint of a heating roll, the direction of the axis O between the mounting portion 4 attached to the rotating body and the first bearing member 19 Even if the interval between the first and second sealing materials 17A, 17B is large in the direction of the axis O, the upper portion of the lower portion of the first and second sealing materials 17A, 17B depends on the weight of the rotor 1. Can be avoided. Therefore, such uneven wear increases with the rotation of the rotor 1 and the objects to be sealed by the first and second sealing materials 17A and 17B (in this embodiment, the supply communication chamber 15 and the discharge communication chamber 16). Since it is possible to prevent leakage of the heat medium (supplied and discharged), processing such as heating and drying by the rotating body can be performed stably over a long period of time.

  In the present embodiment, the heat medium discharge channel 5, the discharge chamber 8, and the supply channel 6 are formed in one rotor 1, and the casing 11 communicates with the discharge channel 5 and the discharge chamber 8. A discharge communication chamber 16 and a supply communication chamber 15 communicating with the supply flow path 6 are formed, and supply and discharge of the heat medium to and from the rotating body are performed simultaneously. The first bearing in the present embodiment is provided between the through hole 14A of the third partition wall 14 and the rotor 1 that partitions the supply communication chamber 15 and the discharge communication chamber 16 of the casing 11 adjacent in the axis O direction. A sliding bearing is interposed as the member 19.

  For this reason, according to the present embodiment, the first bearing member 19 prevents the first and second seal members 17A and 17B from being unevenly worn as described above, and the adjacent supply communication chamber 15 and the discharge communication. Leakage of the heat medium between the chamber 16 can also be suppressed. In particular, since the first bearing member 19 in the present embodiment is an oil-impregnated bearing, the oil film of the impregnated lubricant (lubricating oil) has a high effect of preventing leakage of the heat medium.

  In order to rotatably support the rotor 1 by the first bearing member 19 made of a non-elastic sliding bearing (bush) such as the first and second sealing members 17A and 17B made of the gland packing, this first Although a slight clearance is required between the one bearing member 19 and the outer peripheral surface of the rotor 1, the supply communication chamber 15 partitioned by the third partition wall 14 in which the first bearing member 19 is interposed; Since both the steam tube dryer and the like circulate in the discharge communication chamber 16 are high-temperature steam, even if a slight heat medium leaks from this clearance, there is no problem.

  Furthermore, in this embodiment, since it is possible to avoid the occurrence of uneven wear in the first and second sealing materials 17A and 17B as described above, as these first and second sealing materials 17A and 17B, for example, Without using a special carbon seal ring as described in Patent Document 1, it is possible to use a gland packing that is relatively inexpensive and easy to adjust and replace. For this reason, according to such a rotary joint, it is possible to improve maintainability and reduce costs.

  In the present embodiment, the braided gland packing is used as described above as the first and second sealing members 17A and 17B, which are gland packings. However, for example, as in a modification of the above embodiment shown in FIG. Alternatively, one or a plurality of die mold gland packings may be used as a pair of first and second sealing materials 24A and 24B, respectively. Here, in the modification shown in FIG. 3, the same reference numerals are assigned to the portions common to the above-described embodiment except for the first and second sealing materials 24 </ b> A and 24 </ b> B.

  Further, in the rotary joint of the present embodiment, the supply flow path 6, the discharge flow path 5, and the discharge chamber 8 of the rotor 1, which are flow paths through which a high-temperature heat medium flows, and the same high-temperature heat medium communicated with these. The second bearing on the most other end side among the plurality of bearing members 19 and 21 that rotatably support the rotor 1 with respect to the supply communication chamber 15 and the discharge communication chamber 16 of the casing 11 that is a communication chamber through which the gas flows. The member 21 is disposed at a position away from at least one (both in the present embodiment) of the other end 1B side of the rotor 1 in the direction of the axis O and the radially outer side of the axis O.

  Accordingly, the heat from the supply flow path 6, the discharge flow path 5, the discharge chamber 8, the supply communication chamber 15, and the discharge communication chamber 16 is dissipated before being transmitted to the second bearing member 21. Even if a general slewing bearing (rolling bearing) as in this embodiment is used as it is as 21, the seizure does not occur due to loss of the lubricant, and the rotor 1 is stably rotated around the axis O. Since the second bearing member 21 can be rotatably supported, the structure of the second bearing member 21 is not complicated.

  Furthermore, the supply flow path 6, the discharge flow path 5, and the discharge chamber 8 and the second bearing member 21 separated from each other, and the supply communication chamber 15 and the discharge communication chamber 16 and the second bearing member 21 are separated. At least one (also both in this embodiment) is provided with a heat radiating chamber 9, a flange 10, a fin 22 of the extending portion 20, and an opening 23 as a heat radiating portion capable of radiating the heat of the heat medium. ing. Therefore, in addition to the second bearing member 21 being away from the flow path and the communication chamber as described above, the heat transmitted to the second bearing member 21 by the heat radiating portion can be efficiently dissipated. Therefore, the second bearing member 21 can be more reliably avoided from being exposed to a high temperature.

  That is, in the present embodiment, first, as the heat radiating section, the supply flow path 6, the discharge flow path 5, and the discharge chamber 8 that are flow paths of the heat medium are isolated from the other end 1 </ b> B side of the rotor 1. The other end of the rotor 1 is provided with a heat radiating chamber 9 that opens to the outside via an opening 9A. According to such a heat radiating chamber 9, heat transferred from the supply flow path 6, the discharge flow path 5, and the discharge chamber 8 of the rotor 1 is dissipated from the outer periphery of the heat radiating chamber 9, and the opening portion is also formed from the heat radiating chamber 9. It is possible to prevent the second bearing member 21 from being exposed to a high temperature by being diffused to the outside through 9A.

  In the present embodiment, secondly, as the heat radiating portion, a flange portion 10 is provided on the other end portion 1B side of the rotor 1 so as to project to the outer peripheral side in the radial direction with respect to the axis O, and the outer peripheral portion of the flange portion 10 is provided. The 2nd bearing member 21 is attached to. For this reason, even if heat is transmitted from the other end 1B of the rotor 1, it is dissipated while reaching the outer peripheral side of the flange 10, and the flange 10 rotates integrally with the rotation of the rotor 1. A high heat dissipation effect can be obtained by cutting.

  Furthermore, in the present embodiment, the other end of the casing 11 on the same side as the other end 1B of the rotor 1 in the direction of the axis O is extended in a cylindrical shape with an interval around the outer periphery of the other end 1B of the rotor 1. The outlet 20 is provided, and communicates with the supply flow path 6, the discharge flow path 5, and the discharge chamber 8 of the rotor 1 to supply and discharge a high-temperature heat medium, and the supply communication chamber 15 and the discharge communication of the casing 11. The heat transmitted from the chamber 16 is also dissipated while being transmitted through the extending portion 20. And in this embodiment, since the fin 22 and the opening part 23 are provided in this extension part 20 as the said 3rd, 4th said heat radiating part, it can promote efficient heat dissipation.

  That is, since the surface area of the extended portion 20 can be increased by providing the fins 22 in the extended portion 20, it is possible to improve the heat dissipation effect. Moreover, when the opening part 23 is provided in the extension part 20, while being able to dissipate the heat which propagates the extension part 20 from the inner periphery of this opening part 23, the other end part 1B of the rotor 1 in the extension part 20 Is exposed from the opening 23, the heat transmitted from the flow path of the rotor 1 to the other end 1 </ b> B can be dissipated through the opening 23 without being trapped in the extension 20.

  In addition, you may provide such a fin and opening part in the outer peripheral part of the other end part 1B of the rotor 1, or the flange part 10. FIG. If an opening is provided in the other end 1B of the rotor 1 provided with the heat radiating chamber 9, the heat dissipated in the heat radiating chamber 9 is discharged between the opening 20 other than the opening 9A and the extending portion 20. In addition, if the flange portion 10 is also provided with an opening portion, the heat thus discharged can be discharged to the outside from the opening portion other than the opening portion 23 of the extension portion 20. Further, if fins are provided on the outer periphery of the other end portion 1B of the rotating rotor 1 or the flange portion 10, it is possible to promote more efficient heat dissipation.

  In the present embodiment, the second bearing member 21 has a supply communication chamber of the casing 11 which is a communication chamber with the supply flow path 6 of the rotor 1, which is a flow path of the heat medium, the discharge flow path 5, and the discharge chamber 8. 15 and the discharge communication chamber 16 are disposed at positions away from both the other end 1B side in the direction of the axis O and the outer peripheral side in the radial direction with respect to the axis O, but are separated only in the direction of the axis O and have a diameter. It may be at the same position in the direction, or conversely, it may be at the same position in the direction of the axis O and separated only on the radially outer side. However, in these cases, the rotor 1 and the extending portion 20 are elongated in the direction of the axis O, or the second bearing member 21 is required to have a large diameter. It is desirable that the bearing member 21 be disposed at a position away from the path and the communication chamber in both the axis O direction and the radial direction.

  Furthermore, the distance between the flow path and communication chamber of the heat medium as described above and the second bearing member 21 depends on the length in the direction of the axis O of the other end 1B of the rotor 1 to which heat is transmitted and the other end 1B. The sum of the length in the radial direction from the outer periphery to the second bearing member 21 along the flange portion 10 or the length in the axis O direction of the extension portion 20 and the diameter to the bearing member 21 along the extension flange portion 20C. The sum of the lengths in the direction is desirably 200 mm or more, and more desirably 400 mm or more. If the distance is shorter than this, there is a possibility that sufficient heat dissipation cannot be achieved before reaching the second bearing member 21 depending on the temperature of the heat medium and the heat radiation effect of the heat radiation portion.

  On the other hand, in the present embodiment, the heat radiating chamber 9 and the flange portion 10 are provided as the first and second heat radiating portions between the flow path of the heat medium and the bearing member 21, and between the communication chamber and the bearing member 21. Although the fin 22 and the opening part 23 are provided in the extended part 20 as the 3rd and 4th heat radiating part, the heat radiating part may be provided only between either one. For example, since the extending part 20 is disposed on the outer periphery of the rotor 1 and exposed to the outside air, the fins 22 and the opening part 23 are not provided, or the opening part 23 is covered with a cover as necessary. Also good.

  Further, the other end portion 1B of the rotor 1 provided with such a heat radiating portion and the extended portion 20 of the casing 11 are air-cooled by blowing air with a fan or the like, or in some cases water-cooled to forcibly. Cooling may be performed. In the present embodiment, the rotor 1 is provided with a heat medium discharge channel 5 and a supply channel 6, and the casing 11 is provided with a heat medium supply communication chamber 15 and a discharge communication chamber 16. Although one rotary joint supplies and discharges the heat medium to the rotating body, only the discharge flow path 5 and the discharge communication chamber 16 are provided to discharge only the heat medium that has become a liquid medium. May be.

  In the present embodiment, the space in the inner tube 2 of the rotor 1 is connected to the heat medium discharge side of the rotating body to serve as a heat medium discharge flow path 5, while the space between the rotor 1 and the inner tube 2. The space is connected to the heat medium supply side of the rotating body and serves as a heat medium supply flow path 6. On the contrary, the space in the inner tube 2 serves as the heat medium supply flow path 6, The space between the rotor 1 and the inner pipe 2 can be used as a heat medium discharge flow path 5, and the communication chamber communicating with these can also be supplied and discharged in a reverse configuration. In this case, a portion indicated by reference numeral 6A in FIGS. 2 and 3 serves as a discharge port, and the shielding member is provided at least between the discharge port and the first seal members 17A and 24A.

DESCRIPTION OF SYMBOLS 1 Rotor 1A One end part of the rotor 1 1B Other end part of the rotor 1 2 Inner pipe 4 Attachment part 5 Discharge flow path 6 Supply flow path 6A Supply port 8 Discharge chamber 8A Discharge port 8B Shielding member 9 Heat radiation chamber 9A Opening of the heat radiation chamber 9 Part 10 Flange part 10A Opening part of flange part 11 Casing 12-14 First to third partition walls 12A-14A Through hole of first to third partition walls 12-14 15 Supply communication chamber 15A Supply pipe 16 Discharge Communication chamber 16A Discharge pipes 17A, 24A First seal material 17B, 24B Second seal material 18 Packing retainer 19 First bearing member 20 Extension portion 20C Extension flange portion 21 Second bearing member 22 Fin 23 Extension Opening of part 20 O Axis of rotor 1

Claims (4)

A cylindrical rotor having one end attached coaxially to the rotating shaft of the rotating body and rotated around the axis;
A casing disposed on the outer periphery of the rotor,
Inside the rotor, there is a flow path through which the liquid medium that is opened at one end in the axial direction of the rotor flows and discharged from the rotating body, and the liquid medium that communicates with the other end of the flow path. And a discharge chamber formed so that a discharge port through which the gas is discharged opens to the outer peripheral portion of the rotor,
The casing is formed with a communication chamber communicating with the discharge port,
Between the rotor and the casing, a seal material for sealing the space between the rotor and the casing is disposed at a position away from the discharge port in the axial direction.
A rotary joint characterized in that a shielding member protruding from the outer peripheral portion of the rotor is provided between the discharge port of the rotor and the sealing material in the axial direction.   The rotary joint according to claim 1, wherein the shielding member is a cylindrical member protruding from around the discharge port.   The rotary joint according to claim 1 or 2, wherein the other end portion of the flow path in the axial direction protrudes to the other end side in the axial direction in the discharge chamber.   The other end of the flow path in the axial direction protrudes from the edge of the discharge port in the axial direction to the other end in the axial direction in the discharge chamber. Item 4. The rotary joint according to Item 3.

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