KR102395143B1 - Heat transfer disc spindle equipped with condensate drain system, and Disc-type dryer equipped with this - Google Patents

Abstract

The present invention relates to: a heat transfer disk spindle device equipped with a condensate discharge device capable of preventing a decrease in thermal efficiency due to condensate by discharging the condensate generated by condensation of high-temperature steam supplied to a heat transfer spindle and a heat transfer disk; and a disk-type drying device equipped with the same. According to the present invention, the heat transfer disk spindle device equipped with a condensate discharge device comprises: a steam supply port through which steam, which is a heat medium, is supplied in one side; a heat transfer spindle which is formed in a form of a hollow tube having a condensate outlet for discharging condensate on the other side; and a heat transfer disk installed in plural at predetermined intervals in the heat transfer spindle and is configured to allow the steam supplied through a hole for a heat medium to communicate with each other. The heat transfer disk spindle device includes at least one of a condensate discharge device for a heat transfer spindle configured to guide and discharge condensate in the heat transfer spindle to a condensate outlet when rotating in one side of the heat transfer spindle where the condensate outlet is formed; or a condensate discharge device for a heat transfer disk configured to discharge condensate in a heat transfer disk to an inside of the heat transfer spindle when rotating through a hole for a heat medium.

Description

Heat transfer disc spindle equipped with condensate drain system, and Disc-type dryer equipped with this}

The present invention relates to a heat transfer spindle provided with a plurality of heat transfer disks using high-temperature steam as a heating medium at predetermined intervals, and to a disk-type drying apparatus having the same.

In detail, an electrothermal disk spindle device equipped with a condensate discharge device configured to prevent a decrease in thermal efficiency due to condensate by discharging condensed water generated by condensing the high-temperature steam supplied to the heat transfer spindle and the heat transfer disk, and a disk having the same It relates to a type drying device.

In general, facilities that reprocess food waste as feed or wastewater treatment facilities such as wastewater can perform the next step or reduce incineration cost by removing moisture contained in these treatment objects.

For this purpose, drying treatment of various food wastes or by-products generated in the wastewater treatment process is required, and for this purpose, various types of drying treatment devices are used.

Among the drying apparatuses of various drying methods, a disk-type drying apparatus having a disk structure as shown in FIG. 1 is widely used, and various technologies have been developed as described in patent documents.

Referring to Figure 1,

A general disk-type drying device includes a cylindrical drying body (1) that is fixed on the floor and made to be dried and discharged after by-products to be dried are put in, and an electrothermal disk spindle device (2) which is rotated and installed through the drying body; , a driving device (3) for driving the electrothermal disk spindle device.

The heat transfer disk spindle device (2) includes a hollow type heat transfer spindle (10), a heat transfer disk (20) formed at regular intervals outside the heat transfer spindle (10), and a heating element on one side of the heat transfer spindle (10). The steam supply port 11 to which steam is supplied and the condensate water outlet 12 for discharging condensed water are formed on the other side, and the heat medium for the stem to communicate with the heat transfer spindle 10 and the heat transfer disk 20 A hole 30 is formed.

In such a disk-type drying device, the heat transfer disk 20 is heated by steam, which is a heat medium supplied to the inside of the rotating heat transfer spindle 10 , and the heated heat transfer disk 20 contains the dry matter put into the drying body 1 and It consists of a structure that is dried by contact.

2 to 4,

Steam (steam) as a heating medium is supplied to the spindle inner space 10a through a steam supply port 11 formed on one side of the heat transfer spindle 10, and the supplied steam is supplied through a hole 30 for a heating medium. The heat transfer disk 20 is heated by being supplied to the disk inner space 20a of each heat transfer disk 20 installed at an interval of .

The supplied steam is condensed so that a large amount of condensed water exists in the spindle inner space 10a and the disk inner space 20a.

A part of the condensed water existing in the disk inner space 20a is discharged to the spindle inner space 10a through the heat medium hole 30 when the heat transfer spindle 10 rotates.

Referring to Figure 4,

In order to discharge the condensed water in the spindle inner space 10a, the inner end 13 of the condensed water outlet 12 is formed to be close to the inner circumferential surface of the heat transfer spindle 10 in the downward direction, so that the condensed water is It is made to be discharged to the outside through the condensate outlet (12).

However, even when discharged in this way, a large amount of condensed water remains in the spindle inner space 10a and the disk inner space 20a.

Due to such a large amount of condensed water remaining, the drying efficiency is lowered due to reasons such as the difficulty in reaching the set temperature of the heat transfer disk 20 or not being heated to a temperature of 100° C. or higher.

In addition, when operation is temporarily suspended (steam supply is stopped), all of the supplied steam is condensed into condensed water, and the condensed water is not discharged to the outside.

In this way, when reheating by supplying steam by condensate that is not discharged to the outside, heating time is cut off by reheating a large amount of condensed water remaining together with the heat transfer disk, and there is a problem that the thermal efficiency is lowered due to heating of the remaining condensate. will do

(KR) Registered Patent 10-0485934 (KR) Registered Patent 10-0704399 (KR) Registered Patent 10-1100899 (KR) Registered Patent 10-0952740 (KR) Registered Patent 10-1826059

An object of the present invention is to solve a problem that occurs because condensed water generated in a heat transfer disk spindle device of a disk-type drying device is not discharged to the outside.

The present invention provides a heat transfer disk spindle device configured to discharge the heat transfer spindle and condensed water generated in the internal space of the heat transfer disk even when steam is not supplied, and a disk-type drying device including the heat transfer disk spindle device want to

That is, the present invention is to provide an electrothermal disk spindle device equipped with a condensed water discharging device configured to discharge condensed water generated in the inner space of the spindle of the heat transfer spindle or the disk inner space of the heat transfer disk during rotation of the heat transfer disk spindle device. do.

The object of the present invention as described above is a heat transfer spindle in the form of a hollow tube having a steam supply port to which steam as a heating medium is supplied to one side and a condensate water outlet to discharge condensed water to the other side, and a plurality of the heat transfer spindles are provided at predetermined intervals. In the heat transfer disk spindle device comprising a heat transfer disk installed and configured to allow steam supplied through a hole for a heat medium to communicate with each other, one side of the heat transfer spindle having a condensate outlet is provided to guide the condensate in the heat transfer spindle to the condensate outlet when rotating. a condensate draining device for the heat transfer spindle; Alternatively, the heat transfer disk spindle device provided with a condensate discharge device including any one or more of the condensate water discharge devices for the heat transfer disk configured to discharge the condensed water in the heat transfer disk into the heat transfer spindle during rotation through the hole for the heat medium can be solved. .

The condensate discharging device for the heat transfer spindle includes: a diaphragm for a collection space provided with a condensate inlet through which condensed water flows when the heat dissipation rotates, and configured to form a condensate collecting space for discharging toward the condensate outlet; and a guide diaphragm configured to guide the condensed water flowing into the condensed water collecting space to the condensed water outlet when the electrothermal disspins rotate.

In the condensate inlet, two long holes are formed at equal intervals, and are formed on the outer periphery side of the diaphragm for the collection space to be in contact with or close to the inner circumferential surface of the heat transfer dispins, and the guide diaphragm corresponds to the number of condensate inlets. The condensed water collecting space is divided into a plurality of individual condensed water collecting spaces, and the individual condensed water collecting space has respective condensed water inlets.

The condensed water discharging device for the heat transfer disk corresponds to the heat medium hole, and when rotating, the condensed water accumulated in the lower portion of the disk inner space is moved to the upper portion and discharged into the heat transfer spindle through the heat medium hole. Condensate drain plate for; and a condensate guide plate for a disk formed on the opposite side to the condensate discharge plate for the disk based on the hole for the heat medium to guide the condensed water moved to the condensate discharge plate for the disk to flow into the hole for the heat medium.

The heat medium hole formed in each of the heat transfer disks consists of two heat medium holes facing each other, and an induction connector for connecting the two heat medium holes is installed inside the heat transfer dispindle, and the induction connector pipe A partition plate configured to partition on both sides and a hole for inflow and discharge are formed on both sides of the partition plate based on the partition plate, respectively.

In the heat transfer disk spindle device provided with the condensate discharge device of the present invention made as described above, the condensed water in the inner space of the heat transfer spindle or the inner space of the heat transfer disk can be discharged to the outside during rotation. It is possible to discharge condensed water in the inner space of the heat transfer spindle or the inner space of the heat transfer disk.

In addition, since the condensate remaining in the inner space of the heat transfer spindle or the inner space of the heat transfer disk can be discharged to the outside when the supply of steam is stopped, the heat transfer disk can be quickly preheated even after operation is stopped and restarted. It is possible to prevent a decrease in thermal efficiency that occurs in the remaining condensate.

In addition, since the number of condensate remaining in the inner space of the heat transfer spindle or the inner space of the heat transfer disk is small, the temperature of the heat transfer disk can be maintained high, thereby increasing the drying efficiency.

In addition, the rigidity of the heat transfer spindle can be increased by the connection pipe for induction connecting the heat medium hole installed in the inner space to the heat transfer spindle, so that phenomena such as bending and distortion can be prevented.

1 is a schematic view of a disk-type drying apparatus in practice in the prior art.
2 is a schematic front view of a heat transfer disk spindle device in use in a conventional disk-type drying device.
3 is a schematic cross-sectional side view of a heat transfer disk spindle device in use in a conventional disk-type drying device.
4 is a front cross-sectional schematic view of a heat transfer disk spindle device in use in a conventional disk-type drying device.
5 is a schematic front view of an electrothermal disk spindle device according to an embodiment of the present invention;
6 is a cross-sectional schematic view of a condensate outlet portion of the heat transfer disk spindle device according to an embodiment of the present invention.
7 is a schematic side cross-sectional view of a heat transfer disk spindle device for explaining an apparatus for discharging condensed water for a heat transfer spindle according to an embodiment of the present invention.
8 and 9 are partial perspective schematic views of a condensate discharge device for a heat transfer spindle of a heat transfer disk spindle device according to an embodiment of the present invention.
10 is a perspective schematic view of a partial section of a heat transfer disk for explaining an apparatus for discharging condensed water for a heat transfer disk according to an embodiment of the present invention;
11 is a schematic cross-sectional front view of a heat transfer disk for explaining an apparatus for discharging condensed water for a heat transfer disk according to an embodiment of the present invention.
12 is a schematic cross-sectional side view of a heat transfer disk for explaining an apparatus for discharging condensed water for a heat transfer disk according to an embodiment of the present invention.

The terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention. It should be understood that, since it does not represent all of the technical spirit of the present invention, there may be various equivalents and modifications that can be substituted for them at the time of the present application.

The present invention relates to a disk-type drying device for drying food waste or by-products generated during wastewater treatment.

The heat transfer disk spindle device equipped with the condensate discharge device of the present invention is installed and used in a disk-type drying device.

The present invention provides a heat transfer disk spindle device equipped with a condensate discharge device, a heat transfer spindle in the form of a hollow tube having a steam supply port through which steam as a heating medium is supplied to one side and a condensate discharge port through the other side for discharging condensed water, and the heat transfer spindle. In a heat transfer disk spindle device including a heat transfer disk installed at a predetermined interval and configured to allow steam supplied through a heat medium hole to communicate with each other, the condensed water generated by the condensation phenomenon only by rotation without supplying steam is transferred to the heat transfer spindle and heat transfer spindle It is made so that it can be removed from the disk.

The present invention will be described in detail with reference to the drawings showing embodiments.

5 and 6,

The present inventor's heat transfer disk spindle device equipped with a condensate discharge device has a hollow tube (cylindrical type) having a steam supply port 11 through which steam is supplied and a condensate discharge port 12 through which condensed water generated due to condensation is discharged to the other side. A heat transfer spindle 10 formed as a tube of) and having a spindle inner space 10a, and a heat transfer disk 20 having a disk inner space 20a installed at a predetermined interval on the outer periphery of the heat transfer spindle 10 and , a hole 30 for a heat medium formed so that the spindle inner space 10a and the disk inner space 20a communicate with each other so that each heat transfer disk 20 is heated by steam, and both sides of the heat transfer spindle 10 The condensed water in the heat transfer spindle 10 is transferred to the condensate outlet 12 when the byproduct transfer blade 40 formed in the form of a screw blade at the outer end portion and the condensate outlet 12 are formed on one side of the heat transfer spindle 10 rotates. The condensed water discharging device 100 for the heat transfer spindle configured to guide and discharge, and the condensed water in the heat transfer disk 20 during rotation through the heat medium hole 30 into the spindle inner space 10a inside the heat transfer spindle 10 It consists of a condensed water discharging device 200 for a heat transfer disk configured to be discharged.

6 to 9 ,

The condensed water discharging device 100 for the heat transfer spindle is formed on one side of the spindle inner space 10a in which the condensed water outlet 12 is formed. ) is configured to guide and discharge.

The condensate discharging device 100 for the heat transfer spindle is installed on one side of the spindle inner space 10a in which the condensate outlet 12 is formed to form a condensed water collecting space 120 for discharge. and a guide diaphragm 130 configured to guide the condensed water flowing into the condensed water collecting space 120 to the condensed water outlet 12 when the electrothermal disspindle 10 rotates.

The condensate inlet 111 for allowing the condensed water in the spindle inner space 10a to flow into the condensed water collecting space 120 is formed in the diaphragm 110 for the collection space, and the condensate inlet 111 is in the form of a long hole. It is formed on the outer periphery side of the diaphragm 110 for the collection space and is formed so as to be in contact with or close to the inner peripheral surface of the heat transfer dispindle 10 .

2 to 4 of the condensate inlets 111 may be formed at equal intervals, and two are preferably formed to have a phase of 180 degrees as shown in FIG. 7 .

The guide diaphragm 130 is configured such that the condensed water introduced into the condensed water collecting space 120 through the condensed water inlet 111 during rotation is discharged through the condensed water outlet 12 .

The guide diaphragm 130 is formed in the condensed water collecting space 120 to correspond to the number of condensate inlet 111, so that it can be divided into a plurality of individual condensed water collecting space 120a, 120b. Consists of (130a, 130b), the individual condensed water collecting space (120a, 120b) is formed to have each condensed water inlet (111).

The guide diaphragm 130 includes a condensed water movement guide diaphragm 131 that moves the condensed water flowing into the condensed water collecting space 120 to the upper portion during rotation, and the condensed water movement guide diaphragm 131. and a condensate guide diaphragm 132 for guiding the condensed water extending and moving to the upper portion to the condensate outlet 12 .

The guide diaphragm 130 is a condensed water movement guide diaphragm 131, the condensate inlet 111 is installed to be spaced apart (to have a phase) by a predetermined distance, so that the condensed water flows into the condensed water inlet 111 during rotation. Then, the condensed water introduced into the condensed water collecting space 120 is moved upward by the condensed water movement guide diaphragm 131 .

In the condensed water discharging device 100 for the heat transfer spindle made as described above, the condensed water generated as a result of condensation in the spindle inner space 10a during rotation flows into the condensed water collecting space 120 through the condensed water inlet 111, and the The condensed water introduced into the condensed water collection space 120 is moved upward by the condensed water movement guide diaphragm 131, and the condensed water moved in the upward direction is condensed water outlet 12 along the condensed water induction guide diaphragm 132. ) and discharged to the outside.

10 to 12 ,

The condensed water discharge device 200 for the heat transfer disk is configured to discharge the condensed water generated by the condensation phenomenon in the disk inner space 20a to the spindle inner space 10a during rotation.

The condensed water discharging device 200 for the heat transfer disk moves the condensed water accumulated in the lower portion of the disk inner space 20a to the upper portion during rotation, and discharges it into the heat transfer spindle 10 through the hole 30 for the heat medium. The condensed water discharge plate 210 for the disk, which is formed on the opposite side to the condensate discharge plate 210 for the disk based on the hole 30 for the heat medium, and the condensed water moved to the condensate discharge plate 210 for the disk is used for the heat medium The condensate guide plate 220 for disk to guide the inflow into the hole 30, and the hole 30 for the heat medium formed of two heat medium holes 31 and 32 facing each other and the both ends are connected to each other for induction It includes a connector 230 .

The condensed water discharge plate 210 for the disk is installed near the hole 30 for the heat medium and moves from the lower side to the upper side when the condensed water condensed in the disk inner space 20a is rotated. It is preferable to install in the same way.

The condensate guide plate 220 for the disk is installed on the opposite side of the condensate drain plate 210 for the disk with respect to the hole 30 for the heat medium, and the condensed water that is moved to the condensate drain plate 210 for the disk is the hole 30 for the heat medium ) so that it can be easily introduced into the

The induction connector 230 has both ends respectively installed in the two heat medium holes 31 and 32 facing each other, and a partition plate 231 configured to partition on both sides is formed in the middle part, and the partition plate ( 231), inlet and outlet holes 232 and 233 are formed on both sides, respectively.

During rotation through the inlet and outlet holes 232 and 233, steam from the spindle inner space 10a flows into the disk inner space 20a, and the condensed water from the disk inner space 20a is discharged into the spindle inner space 10a. (see Fig. 12).

The connection pipe 230 for induction is installed perpendicularly to the connection pipe 230' for proximity induction installed on the adjacent heat transfer disk 20. That is, the heat medium hole 30 formed in the heat transfer disk 20 and the heat medium hole 30 formed in the heat transfer disk 20 adjacent to each other have a phase difference of 90 degrees, and both ends are connected to the heat medium hole 30 . The connection pipe 230 for induction and the connection pipe 230' for induction are orthogonal to each other.

The condensed water discharging device 200 for the heat transfer disk made in this way moves upwards by the condensate discharging plate 210 for the disc when rotating as shown in FIG. The condensed water moved upward by the condensate discharge plate 210 flows into the induction connection pipe 230 through the heat medium hole 30 located on the upper side, and is discharged through the inflow/discharge hole 232 to the spindle inner space 10a. ), and the steam of the spindle inner space 10a flows into the inlet/outlet hole 233 and flows into the disk inner space 20a through the heat medium hole 30 located on the lower side.

In the heat transfer disk spindle device provided with the condensate discharge device of the present invention, the condensate generated by the condensation phenomenon in the disk inner space 20a by the condensate water discharge device 200 for the heat transfer disk when rotating without supply of steam is condensed into the spindle inner space ( 10a), and the condensed water in the spindle inner space 10a is moved to the condensed water collection space 120 for discharge by the condensed water discharge device 100 for the electrothermal spindle, and the condensed water outlet by the guide diaphragm 130 12) is released.

10: electric spindle 11: steam supply port
12: condensate outlet 10a: internal space
20: electric disk 20a: internal space
100: condensate discharge device for electric heat spindle
110: diaphragm for collection space 111: condensate inlet
120, 120a, 120b: Condensate collection space for discharge
130: guide plate
200: condensate discharge device for electric disk
210: condensate drain plate for disk
220: condensate guide plate for disk
230: connector for induction

Claims (6)

A heat transfer spindle in the form of a hollow tube having a steam supply port to which steam as a heating medium is supplied to one side and a condensate water outlet to discharge condensate water to the other side, and a plurality of heat transfer spindles are installed at a predetermined interval and supplied through a hole for a heating medium In the heat transfer disk spindle device including a heat transfer disk configured to communicate with each other,
The condensate discharge device 100 for the heat transfer spindle is configured to guide the condensed water in the heat transfer spindle 10 to the condensate outlet 12 to discharge the condensate in the heat transfer spindle 10 when rotating but,
The condensate discharge device 100 for the heat transfer spindle,
A diaphragm 110 for a collection space provided with a condensate inlet 111 through which condensed water is introduced when the heat transfer spindle 10 is rotated, and configured to form a condensate collecting space 120 for discharging toward the condensate outlet 12; Electric heat provided with a condensate discharge device, characterized in that it includes a guide diaphragm 130 configured to guide the condensed water flowing into the condensed water collecting space 120 to the condensed water outlet 12 when the heat transfer spindle 10 rotates. disk spindle unit. According to claim 1,
The condensate inlet 111 has 2 to 4 long holes formed at equal intervals, is formed on the outer periphery side of the diaphragm 110 for the collection space, and is formed to contact or close to the inner circumferential surface of the heat transfer spindle 10,
The guide diaphragm 130 divides the condensed water collecting space 120 into a plurality of individual condensed water collecting space parts 120a and 120b to correspond to the number of condensed water inlets 111, and the individual condensed water collecting space 120a , 120b) is provided with a condensate discharge device, characterized in that each of the condensate inlet 111 is provided with an electrothermal disk spindle device. According to claim 1,
It further includes a condensed water discharge device 200 for a heat transfer disk configured to discharge the condensed water in the heat transfer disk 20 into the heat transfer spindle 10 during rotation through the hole 30 for the heat medium,
The condensed water discharging device 200 for the heat transfer disk is configured to move the condensed water accumulated in the lower portion of the inner space of the disk to the upper portion during rotation to discharge it into the heat transfer spindle 10 through the hole 30 for the heat medium. Electrothermal disk spindle device provided with a condensate discharge device, characterized in that it includes a condensate discharge plate (210) for the disk. 4. The method of claim 3,
The condensate formed on the opposite side of the condensate discharge plate 210 for the disk and moved to the condensed water discharge plate 210 for the disk based on the hole 30 for the heating medium is to be introduced into the hole 30 for the heating medium. Condensate guide plate 220 for the disk and;
The heat medium hole 30 formed in each of the heat transfer disks 20 consists of two heat medium holes 31 and 32 facing each other,
A connection pipe 230 for induction connecting the two holes 31 and 32 for the heat medium is installed inside the heat transfer spindle 10,
In the middle portion of the induction connector 230, a partition plate 231 configured to partition on both sides, and holes 232 and 233 for inflow and discharge are formed on both sides based on the partition plate 231, respectively. Electrothermal disk spindle device equipped with a condensate discharge device. [Claim 5] A disk-type drying apparatus having a heat transfer disk spindle apparatus equipped with a condensate discharge apparatus according to any one of claims 1 to 4. delete

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