JP2009243721A - Indirect heating type rotary dryer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress generation of cracking on mounting sections of supporting members or a rotary cylinder, and to easily improve even an existing rotary cylinder. <P>SOLUTION: In this indirect heating type rotary drier, a number of heat transfer pipes 21 are circularly disposed on the whole inner peripheral part excluding an axis section, of a rotary drier body 1 in a cylindrical rotary drier body 1, a number of supporting members 41 projecting toward the axis section of the rotary drier body 1, are disposed on an inner peripheral face of the rotary drier body 1, and the heat transfer tubes 21 are supported by the supporting members 41. Projecting ends 43 of the supporting members 41 adjacent to each other in the peripheral direction of the rotary drier body 1 are respectively connected with each other through rod bodies 45. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an indirectly heated rotary dryer, and more particularly to a horizontal indirect heated rotary dryer.

  As a horizontal indirect heating rotary dryer, for example, a steam tube dryer as shown in FIG. 9 is known. Such a steam tube dryer has a large heating area per volume. Therefore, there is a feature that the drying capacity is large and the heat transfer rate is high. Furthermore, it is frequently used because it has advantages such as not requiring an exhaust gas treatment facility and easy operation.

  In general, the steam tube dryer 101 has a rotating cylinder 110 having a length of about 10 m to 30 m, and a heating tube in which raw materials (for example, wet powder, granular powder, etc.) are heated by steam in the rotating cylinder 110. 111, and the raw material is sequentially moved to the discharge port 112 as the rotary cylinder 110 rotates, so that the raw material is continuously dried.

  As shown in FIG. 10, the heating tubes 111 are arranged in an annular shape over the entire inner peripheral portion excluding the shaft core portion of the rotating cylinder 110. Furthermore, support plates 118U and 118L projecting from the inner peripheral surface of the rotation tube 110 toward the axial core portion of the rotation tube 110 are provided in the rotation tube 110, and the heating tube 111 is attached to these support plates 118U and 118L. By being inserted, it is supported on the inner peripheral surface of the rotating cylinder 110. The group of the support plates 118U and the group of the support plates 118L are provided at a predetermined interval in the longitudinal direction of the rotating cylinder 110 as shown in FIG.

  The rotating cylinder 110 is deformed into an oval shape by rotation, the action of its own weight and heat, etc., and due to this deformation, stress concentration occurs at the base portions of the supporting members 118U and 118L supporting the heating tube 111, and the supporting member Since breakage such as cracks occurs in the mounting portions of 118U and 118L or the rotating cylinder 110, a reinforcing ring 119 over the entire inner peripheral surface is provided on the inner peripheral surface of the rotating cylinder 110 in two stages, as shown in FIG. The support member 118U is provided on one reinforcing ring 119, and the support member 118L is provided on the other reinforcing ring 119 (see, for example, Patent Document 1).

However, when a reinforcing ring is provided over the entire inner peripheral surface on the inner peripheral surface of the rotating cylinder, or a reinforcing ring is provided over the entire outer peripheral surface on the outer peripheral surface of the rotating cylinder, a certain degree of effect is obtained. However, it was not always satisfactory. Further, conventionally, since it is necessary to weld the reinforcing ring over the entire length of the inner peripheral surface or the outer peripheral surface of the rotating cylinder, it is not easy to attach the reinforcing ring. Further, even if an attempt is made to modify an existing rotating cylinder, it has been impossible to provide a reinforcing ring on the inner peripheral surface of the rotating cylinder.
JP 2006-57880 A

  The present invention has been made in order to solve such problems, and the object of the present invention is to only suppress the occurrence of cracks or the like in the mounting portion of the support member or the rotating cylinder. In addition, the present invention is to provide an indirect heating type rotary dryer that can be easily modified even with an existing rotary cylinder.

  The indirect heating rotary dryer according to claim 1 of the present application has a large number of heat transfer tubes arranged in an annular shape over the entire inner peripheral portion excluding the shaft core portion of the rotary dryer main body in a cylindrical rotary dryer main body, In the indirect heating type rotary dryer in which the inner peripheral surface of the rotary dryer main body is provided with a number of support members protruding toward the axial core portion of the rotary dryer main body, and the support member supports the heat transfer tube, The protruding ends of the support members adjacent in the circumferential direction of the rotary dryer main body are connected to each other through a rod-shaped body.

  The indirect heating rotary dryer according to claim 2 of the present application has a large number of heat transfer tubes in a cylindrical rotary dryer main body arranged in an annular shape over the entire inner peripheral portion excluding the shaft core portion of the rotary dryer main body, In the indirect heating type rotary dryer in which the inner peripheral surface of the rotary dryer main body is provided with a number of support members protruding toward the axial core portion of the rotary dryer main body, and the support member supports the heat transfer tube, The protruding ends of the supporting members adjacent in the circumferential direction of the rotary dryer main body are connected to each other by an annular body having the same diameter as the protruding end of the supporting member.

  In the invention according to claim 1 of the present application, a large number of heat transfer tubes are arranged in an annular shape over the entire inner peripheral portion excluding the shaft core portion of the rotary dryer main body in the cylindrical rotary dryer main body. In the indirect heating rotary dryer in which a large number of support members projecting toward the shaft core portion of the rotary dryer main body are provided on the inner peripheral surface, and the heat transfer tube is supported by the support member, the rotary dryer main body Since the protruding ends of the support members adjacent to each other in the circumferential direction are connected to each other via a rod-like body, it is possible to suppress deformation of the rotary dryer body due to rotation, self-weight and heat action, etc. Become.

  For this reason, it is possible to suppress the stress concentration generated at the base portion of the support member that supports the heat transfer tube, thereby suppressing breakage such as cracks in the attachment portion of the support member or the rotary dryer main body. it can. Further, since the welding of the rod-shaped body is only at both end portions of the rod-shaped body, the welding length is greatly reduced as compared with the conventional reinforcing ring, which contributes to shortening the work period. Further, since the rod-like body can be retrofitted, the existing rotating cylinder can be easily modified.

  In the invention according to claim 2 of the present application, a large number of heat transfer tubes are annularly arranged in the cylindrical rotary dryer body on the entire inner peripheral portion excluding the shaft core portion of the rotary dryer body, and In the indirect heating rotary dryer in which a large number of support members projecting toward the shaft core portion of the rotary dryer main body are provided on the inner peripheral surface, and the heat transfer tube is supported by the support member, the rotary dryer main body The projecting ends of the supporting members adjacent to each other in the circumferential direction are connected to each other by an annular body having the same diameter as the projecting end of the supporting member. Therefore, in synchronization with the invention according to claim 1 of the present application, And it becomes possible to suppress the deformation | transformation of the rotary dryer main body resulting from the effect | action of heat, etc.

  For this reason, it is possible to suppress the stress concentration generated at the base portion of the support member that supports the heat transfer tube, thereby suppressing breakage such as cracks in the attachment portion of the support member or the rotary dryer main body. it can. Further, since the welding of the rod-shaped body is only at both end portions of the rod-shaped body, the welding length is greatly reduced as compared with the conventional reinforcing ring, which contributes to shortening the work period. Further, since the rod-like body can be retrofitted, the existing rotating cylinder can be easily modified.

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

  As shown in FIG. 1, a cylindrical rotary dryer main body 1 constituting a main part of a horizontal indirect heating rotary dryer M is placed on a support roller 3 arranged in the front and rear directions via two tires 2. Riding freely. The rotary dryer body 1 includes an annular large gear 7 between two tires 3, and the large gear 7 meshes with a pinion (not shown). Therefore, the rotary dryer main body 1 can be rotated at a predetermined speed by rotating the pinion by the electric motor 4 including the speed reducer 5. Moreover, the rotary dryer main body 1 is inclined to one side, and the raw material discharge box 11 side is lower than the raw material supply hood 8 side.

  As shown in FIG. 3, the rotary dryer main body 1 includes a large number of heat transfer tubes 21 therein. These heat transfer tubes 21 are annularly arranged on the entire inner peripheral portion excluding the shaft core portion of the rotary dryer main body 1. That is, these heat transfer tubes 21 are arranged at equal intervals on the same circumference having different diameters, and their end portions are attached to an end plate 23a as shown in FIG.

  As shown in FIG. 2, a large number of small holes 22a are provided in the middle of the heat transfer tube 21, and a flat steam chamber 22 is provided surrounding the small holes 22a. As shown in FIG. 3, the steam chamber 22 is multi-divided in the circumferential direction. The right end of the heat transfer tube 21 is blinded by a cover 23. The cover 23 is divided into two or more as a whole to facilitate removal.

  As shown in FIG. 2, a material-raised blade 15 is attached to the right end of the rotary dryer main body 1 in a radial direction from the center of the shaft, and a conical blade back guide plate 16 is provided on the inner side thereof. Guide the material towards the exit. A disc-shaped lid 19 is provided at the tip of the outlet 18 at the front end of the central portion of the material lifting blade 15, and the lid 19 is screwed to the handle 20 via a tube shaft 40. Therefore, by turning the handle 20, the outlet 18 is approached and the processing material discharge degree is adjusted.

  The steam chamber 22 has a steam inlet 30a connected to the pipe 26 of the rotary joint 12a having an introduction port. A medium such as steam is supplied through the steam supply pipe 27, enters the heat transfer pipe 21, and passes through the heat treatment pipe 21. Used for heating. The drain condensed in the heat transfer tube 21 enters the steam chamber 22 through the small hole 22a, enters the tube 30 through the spiral tube 28 and the spiral box 29, is led to the outlet 13 from the center of the rotary joint 12a, and is discharged. . Reference numeral 12 denotes a vapor inlet and 14 denotes a carrier gas inlet.

  An object to be processed which is a raw material is supplied from a raw material supply hood 8 at the left end, and is supplied into the rotary dryer main body 1 by a screw feeder (not shown). The supplied object to be processed is heated and dried in the rotary dryer main body 1 and sent to the right end, guided to the material lifting blade 15 and discharged from the lower portion of the raw material discharge box 11.

  By the way, as shown in FIG.4 and FIG.5, the rotary dryer main body 1 has many flat plate shape (for example, 3-12 sheets) which protrudes toward the axial center part of the rotary dryer main body 1 in the internal peripheral surface. ) Support member 41 is provided. At that time, the support members 41 are installed at equal intervals in the circumferential direction of the rotary dryer main body 1, but arranged so that the front support member 41U and the rear support member 41L do not overlap in front view or rear view. . For example, when there are three support members 41, the front support member 41U is provided at 120 ° intervals starting from the top of the rotary dryer body 1 as shown in FIG. Provided at intervals of 120 ° starting from the lowest part of the rotary dryer body 1.

  The support member 41 is formed in a fan shape, and supports the heat transfer tube 21 by inserting the heat transfer tube 21 through holes 42 provided on the same circumference. The shape of the support member is not limited to the fan shape. For example, although a bowl shape etc. can be considered, when handling property, the arrangement | positioning condition of a heat exchanger tube, etc. are considered, fan-shaped is preferable.

  The most important thing in the present invention is that the protruding ends 43 of the support members 41 adjacent to each other in the circumferential direction of the rotary dryer main body 1 are connected to each other via a rod-like body 45 as shown in FIGS. It is in. More specifically, a square rod-like straight rod-like body 45 is bridged between the front end portions 44a of the side surfaces 44 of the two fan-like support members 41 adjacent to each other in the circumferential direction of the rotary dryer main body 1. At that time, the joint surface between the support member 41 and the rod-like body 45 is joined by welding as shown in FIG.

  As described above, the projecting ends 43 of the support members 41 adjacent to each other in the circumferential direction of the rotary dryer main body 1 are connected to each other via the rod-like body 45, thereby resulting in rotation, self-weight and heat effects. It becomes possible to suppress the deformation of the rotary dryer main body 1. For this reason, the stress concentration which generate | occur | produces in the base part of the support member 41 which is supporting the heat exchanger tube 21 can be suppressed, Therefore, the attachment part of the support member 4, or destruction to a rotary dryer main body 1 with a crack etc. Can be suppressed.

  Further, since welding of the rod-like body 45 is only at both end portions of the rod-like body 45, the welding length is greatly reduced as compared with the conventional cylindrical body. Further, since the rod-like body 45 can be retrofitted, the existing rotating cylinder can be easily modified.

  On the other hand, as shown in FIG. 7, the protruding ends 43 of the support members 41 adjacent in the circumferential direction of the rotary dryer main body 1 have the same diameter as the virtual inscribed circle inscribed in the protruding ends 43 of these support members 41. Even if they are connected to each other by the annular body (ring) 46, the same effect can be obtained. The annular body 46 is not limited to a circle, and may be a hexagon or a dodecagon depending on the number of support members 41.

  The present invention (inner end reinforcing ring method), Conventional Example 1 (outer surface reinforcing ring method), Conventional Example 2 (inner surface reinforcing ring method), and Conventional Example 3 (without reinforcement) are indirect using the finite element method. From the tire lower shell a, the inner diameter side liner b, the outer diameter side liner c, the thrust stopper d, the jackup reinforcing plate mounting portion e, the heat transfer tube support mounting portion f from the inlet, and the inlet of the heating rotary dryer The stress analysis of the second-stage heat transfer tube support mounting portion g and the third-stage heat transfer tube support mounting portion h from the inlet was performed, and the results are shown in FIG.

  In FIG. 8, the solid line indicates the present invention, the two-dot chain line indicates the conventional example 1, the broken line indicates the conventional example 2, and the one-dot chain line indicates the conventional example 3. From FIG. 8, the stress amplitude of the present invention is considerably reduced compared to the conventional examples 1 to 3 for the heat transfer tube support mounting portion h from the first heat transfer tube support mounting portion f of the rotary dryer. I understand that.

The dimensions of each reinforcing ring are as follows. Here, h is the height of the reinforcing ring (see FIG. 5), H is the width of the reinforcing ring (see FIG. 11), and t is the thickness of the reinforcing ring (see FIGS. 11 and 6). The unit of measurement is millimeters.
(1) The present invention: h200 × t30
(2) Conventional example 1: H100 × t30
(3) Conventional example 2: H200 × t50

It is a side view including the partial cross section of the indirect heating type rotary dryer which concerns on this invention. It is an expanded sectional view of the right end part of the indirect heating type rotary dryer concerning the present invention. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG. It is CC sectional drawing of FIG. It is DD sectional drawing of FIG. It is a cross-sectional view of an indirect heating type rotary dryer at the time of using an annular body for connection of a supporting member. It is a figure which shows the stress analysis result of this invention and a prior art example. It is a side view including a partial cross section of a conventional horizontal rotary dryer. It is EE sectional drawing of FIG. It is a principal part expanded sectional view of the conventional horizontal rotary dryer.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Rotating dryer main body 21 Heat transfer tube 41 Support member 45 Rod-shaped body

Claims (2)

  A large number of heat transfer tubes are annularly arranged in the cylindrical rotary dryer body on the entire inner peripheral portion excluding the shaft core portion of the rotary dryer main body, and the shaft of the rotary dryer main body is arranged on the inner peripheral surface of the rotary dryer main body. In the indirect heating type rotary dryer in which a large number of support members projecting toward the core portion are provided and the heat transfer tube is supported by the support member, the support member adjacent to the circumferential direction of the rotary dryer body An indirect heating rotary dryer characterized in that the protruding ends of each other are connected to each other through a rod-like body.   A large number of heat transfer tubes are annularly arranged in the cylindrical rotary dryer body on the entire inner peripheral portion excluding the shaft core portion of the rotary dryer main body, and the shaft of the rotary dryer main body is arranged on the inner peripheral surface of the rotary dryer main body. In the indirect heating type rotary dryer in which a large number of support members projecting toward the core portion are provided and the heat transfer tube is supported by the support member, the support member adjacent to the circumferential direction of the rotary dryer body The projecting ends of the support member are connected to each other by an annular body having the same diameter as the projecting end of the support member.

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