KR102130345B1 - A Steam Dryer - Google Patents

Abstract

The present invention relates to a dryer for drying sludge or food waste containing a large amount of moisture and, more specifically, to a twin spiral steam dryer in which upper and lower body space parts are provided to supply sludge containing moisture to the lower body space part through the upper body space part, a pair of spiral stirrers installed on left and right sides symmetrically to each other in the lower body space part stir the stored sludge as the stirrers rotate in directions opposite to each other while a heater installed in an outer surface part of the lower body space part dries the sludge by applying heat inwards, and a heat loss of the upper body space part is minimized as steam produced during drying is discharged to the outside through a space part provided in an edge part of the upper body space part. Therefore, the twin spiral steam dryer is capable of significantly improving the efficiency of sludge drying.

Description

Twin Spiral Steam Dryer{A Steam Dryer}

The present invention relates to a dryer for drying food waste or sludge containing a large amount of moisture, and more specifically, it is provided with upper and lower double body space portions to supply water-containing sludge to the lower body space portion through the upper body space portion. Then, a pair of spiral stirrers that are installed opposite to each other on the lower body space part rotate the opposite direction to agitate the stored sludge while simultaneously applying heat to the inside through a heater installed on the outer surface part of the lower body space part. The twin spiral that drastically improves the drying efficiency of the sludge by drying the sludge and discharging steam generated during drying to the outside through the space provided at the edge of the upper body space to minimize heat loss in the upper body space. It relates to a steam dryer.

In general, sewage sludge and food waste contain a large amount of water, so it is dehydrated to form less water and is recycled through an intermediate treatment step through final landfill or recycling.

In particular, food waste that is discharged daily in a restaurant or general home can be recycled as an animal feed, high quality compost rich in organic matter, and a fuel supplement when dried while maintaining proper humidity and temperature.

However, when discarded and disposed of together with ordinary household waste, it can contaminate other household waste due to food waste, which can cause many social problems such as odor, environment caused by leachate and waste water, soil, water pollution.

In order to solve this problem, the conventional dehydration and drying facilities have been developed by countries that have achieved high industrial and economic development about 20 years earlier, and have source facilities, and dehydrators that are widely used in industrial sites are belt presses ( Belt press, centrifugal decanter, screw press and filter press are used.

In this dehydrator, in the United States, Japan and EU countries, technology development is progressing in the direction of high-performance, complex, large-sized and eco-friendly dryers. In particular, research and product development for next-generation drying technologies are also actively underway.

Also, the drying facility According to the drying principle, it is divided into heat conduction drying (vacuum drying, drum drying, etc.), radiant drying (high frequency, infrared, etc.), convection drying (hybrid dryer, exhaust gas circulating dryer, fluidized bed dryer, impact jet dryer, etc.). Therefore, it is divided into fluidized bed dryer, drum dryer, and disk dryer.

Conventionally, a lot of disk dryer methods are applied to dry food waste or sludge. The drying method that combines microwave, near infrared wave, hot air, etc. has a high initial device installation cost, high power consumption, Due to the high operating cost, the application is limited.

Therefore, it is urgently needed to develop a dryer that can be dried directly at the workplace where food waste and sewage sludge are generated, and has a low initial installation cost and operation cost, and a high processing capacity per hour.

In addition, recently, a method of drying food waste using high-temperature steam has been proposed, but in this method, heat of steam is not transmitted to the center of the dryer, and only food waste that is biased toward the outer surface of the dryer is dried slightly. Overall, there is a disadvantage in that the drying efficiency and the processing efficiency are low overall, such as having difficulty in dropping the water content as desired while the food waste is gathered like a porridge or curled like a ball.

KR 10-1498123 (Registration No.) 2005.06.21. KR 10-1915527 (Registration No.) 2018.10.31. KR 10-1788390 (Registration No.) 2017.10.13.

Accordingly, the present invention was devised to solve the conventional problems as described above,

It is provided with upper and lower double body spaces to supply sludge containing water to the lower body space through the upper body space, and a pair of spiral agitators installed symmetrically on both sides of the lower body space rotates in opposite directions. An object of the present invention is to provide a twin spiral steam dryer that agitates the stored sludge and simultaneously heats the sludge by applying heat to the inside through a heater installed on the outer surface of the lower body space.

Another object of the present invention is to discharge the steam generated in the lower body space portion during drying of the sludge to the outside through the space portion provided in the edge portion of the upper body space portion and prevent the temperature drop in the upper body space portion to minimize heat loss to minimize the heat loss. It is intended to further improve the drying efficiency.

Another object of the present invention is to install the spiral stirrer installed in the lower body space part on a small pitch spiral part and a large pitch spiral part on one rotation shaft, but install them in a pair so that they are symmetrical on both sides of the left and right sides, and they are in opposite directions. It is intended to be rotated so that the agitation (dispersion) of the sludge is made efficiently.

Another object of the present invention is to install a plurality of heater rods in the upper body space portion to maintain the temperature of the upper body space portion equal to the temperature of the lower body space portion through steam heat generated in the lower body space portion and heat heated in the heater rod. This is to increase the efficiency of the drying operation by minimizing heat loss in the lower body space.

Another object of the present invention is to further install an auxiliary stirrer equipped with a stirring blade on a rotating shaft and an outer surface thereof rotated by a motor on the lower central portion of the lower body space to stir excess sludge that cannot be stirred in a pair of spiral stirrers. This is to improve the efficiency of the stirring operation.

The present invention for achieving the above object is provided with an inlet for supplying a sludge containing moisture and a catalyst to the upper side and the upper body portion 110 is hollow inside; A lower body portion 120 in which a sludge storage space is formed therein while being continuously provided on the lower surface of the upper body portion 110; The stirrer 130 is installed opposite to each other on the inner middle side of the lower body portion 120 and mixing (stirring) the sludge contained inside the lower body portion 120 while mixing and rotating them in opposite directions; Including, the stirrer 130 is a first agitator 140 installed on one side of the middle of the lower body portion 120 and the second agitator 150 symmetrically installed to the other side of the first agitator 140 Are paired with each other; The first agitator 140 is provided on the outside of the first rotating shaft 141 and the lower body 120, the first motor 142 to drive the first rotating shaft 141, the first A first small spiral portion 143 protruding in a small pitch spiral to the outer surface of the rotating shaft 141, and the first small shaft 143, which is provided in succession to the first small spiral portion 143, and has a larger pitch spiral. It includes a first large spiral portion 144 protruding from the outer surface of (141); The second agitator 150 is provided on the outside of the second rotating shaft 151 and the lower body portion 120, a second motor 152 driving the second rotating shaft 151, the second A second small spiral portion 153 protruding in a spiral with a small pitch on the outer surface of the rotating shaft 151, and a second spiral shaft in a spiral with a pitch larger than that provided in succession to the second small spiral portion 153 It includes a second large helix portion 154 protruding from the outer surface of (151), the outer surface of the lower body portion 120 is in contact with the outer surface of the lower surface of the lower body portion 120 in contact with the A plurality of heater plates 160 for heating and supplying heat to the inside of the lower body portion 120 is installed; The first small helix portion 143 of the small pitch and the first large helix portion 144 of the large pitch are configured with a pair of one side spiral blades and the other side spiral blades having different sizes, respectively, and are formed in pairs, respectively. In the coaxial 141, the first small connecting rod which is installed so that both ends of one side of the spiral wing 143 of a small pitch are spaced apart from the first coaxial shaft 141 at regular intervals, and the A second large connecting rod having a height greater than that of the first small connecting rod, provided that both ends of the other spiral blade of the first small spiral portion 143 are spaced apart at regular intervals from the first rotating shaft 141; A third large connecting rod that is installed to form a continuous spiral while both sides of one side of the first large spiral portion 144 of a large pitch are spaced apart at a predetermined interval from the first pivot shaft 141, and the first big spiral portion ( 144) the other end of the other side of the spiral blade is installed to form a continuous spiral spaced apart at a predetermined interval from the first pivot (141), the fourth smaller connecting rod is smaller than the third large connecting rod is provided, the second of the small pitch The small helix portion 153 and the second large helix portion 154 of a large pitch are configured as a pair of opposite one side spiral blades and the other side spiral blades having different sizes, respectively, and the second pivot shaft 151 includes: The fifth small connecting rod and the second small spiral unit (102) are installed so that both ends of one side of the small-wing second small spiral unit 153 are spaced apart at regular intervals from the second pivot shaft 151, and the second small spiral unit (153) 153) the other end of the other side of the spiral blade is installed to form a continuous spiral spaced apart at a predetermined interval from the second pivot shaft 151, the sixth large connecting rod with a height greater than the fifth small connecting rod; The seventh large connecting rod is installed so that one side of the spiral blades of the second large spiral portion 154 of a large pitch is spaced apart at regular intervals from the second pivot shaft 151, and the second large spiral portion ( 154) the other end of the other side of the spiral blade is installed to form a continuous spiral spaced apart at a predetermined interval from the second pivot shaft 151, but is provided with an eight small connector that is smaller than the seventh large connector.

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In addition, the first small spiral portion 143 and the first large spiral portion 144 of a small pitch provided on the outer surface of the first rotating shaft 141 of the first agitator 140 of the present invention, respectively Two spiral protrusions (G) are installed so as to protrude while facing each other and spiral to the outside of the first rotating shaft (141), and on the outer surface of the second rotating shaft (151) of the second agitator (150). The small-sized second small spiral portion 153 and the second large spiral portion 154 are also provided with two spiral protrusions G protruding outward from the second pivot shaft 151, facing each other, and spiraling. It is installed so as to be.

In addition, the pitch (L1) of the first small helix portion 143 and the pitch (L2) of the first large helix portion 144 are in a ratio of 1:2, and the second small helix portion 153 The pitch (L3) and the pitch (L2) of the second large spiral portion 154 are also configured in a ratio of 1:2.

In addition, the first small helical portion 143 provided in the first stirrer 140 and the second small helical portion 153 provided in the second stirrer 150 are installed diagonally opposite each other. In addition, the first large helical portion 144 provided in the first stirrer 140 and the second large helical portion 154 provided in the second stirrer 150 are also installed diagonally opposite to each other.

In addition, the third pivot shaft rotated by the third motor 181a on the lower side between the first stirrer 140 and the second stirrer 150 which is the inner central lower side of the lower body portion 120 of the present invention. A third agitator 180 consisting of 181 and a third agitating blade 182 protruding from the outer circumferential surface of the third coaxial shaft 181 is further installed.

Also, in the upper body portion 110 of the present invention, as they are formed inside the side wall and the upper body, they communicate with each other, and the steam discharge passage for circulating the steam generated inside the lower body portion 120 and circulating it to discharge to the outside ( 113) is provided.

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Twin spiral steam dryer according to the present invention is provided with a double body space portion up and down to supply the sludge containing moisture to the lower body space portion through the upper body space portion, a pair of symmetrical left and right sides installed in the lower body space portion As the spiral stirrer rotates in opposite directions, the stored sludge is stirred, and at the same time, drying efficiency is improved by drying the sludge by applying heat to the inside through a heater installed on the outer surface of the lower body space.

In addition, the present invention discharges the steam generated in the lower body space portion to the outside through the space portion provided in the edge portion of the upper body space portion when drying the sludge to minimize the heat loss of the upper body space portion to further improve the drying efficiency of the sludge. There are advantages.

In addition, the present invention is to install a spiral stirrer installed in the lower body space portion of a small pitch spiral portion and a large pitch spiral portion on one rotation shaft, but install them in a pair so as to be symmetrical on both sides of the left and right sides so that they rotate in opposite directions to each other. The sludge is stirred efficiently.

In addition, the present invention by installing a plurality of heater rods in the upper body space portion to maintain the temperature of the upper body space portion equal to the temperature of the lower body space portion through the steam heat generated in the lower body space portion and heat heated in the heater rod There is an advantage of minimizing heat loss of the lower body space portion to increase the efficiency of the drying operation.

In addition, the present invention further installs an auxiliary stirrer having a rotating shaft and a stirring blade on the outer central surface of the lower body space portion to stir excess sludge that cannot be stirred in a pair of spiral stirrers, thereby improving stirring efficiency. There is an advantage that is further improved.

1 is a schematic state sectional view of a twin spiral steam dryer according to the present invention,
2 is a side cross-sectional view of a twin spiral steam dryer according to the present invention,
Figure 3 is a state cross-sectional view of the plane of the twin spiral steam dryer according to the present invention,
Figure 4 is a state cross-sectional view of the air supply is installed inside the twin spiral steam dryer according to the present invention to supply the air for cleaning,
5 is a schematic state diagram of a twin spiral stirrer installed inside the twin spiral steam dryer according to the present invention to stir sludge, etc.
6 is a state diagram of a heater unit for applying heat to the lower portion of the body of the twin spiral steam dryer according to the present invention,
7 is a working state diagram of the twin spiral steam dryer according to the present invention is supplied with sludge and catalyst to the upper side and the twin spiral stirrer is rotated to stir them.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those of ordinary skill in the art.

Twin spiral steam dryer 100 according to the present invention, as shown in Figures 1 to 7,

The upper side is provided with a first inlet 111 through which food waste or sludge (hereinafter referred to as sludge) containing a lot of water is supplied, and a second inlet 112 through which the catalyst is heated while being mixed with the sludge, and the inside is hollow An upper body portion 110 in a shape;

A lower body part 120 fixed to the support 121 and formed with a sludge storage space therein while being continuously provided on the lower surface of the upper body part 110;

The stirrer 130 is installed opposite to each other on the inner middle side of the lower body portion 120 and mixing (stirring) the sludge contained inside the lower body portion 120 while mixing and rotating them in opposite directions; Includes,

The stirrer 130 has a first stirrer 140 installed on one side of the middle of the lower body portion 120 and a second stirrer 150 symmetrically installed on the other side of the first stirrer 140. In pairs,

The first agitator 140 penetrates the lower body portion 120 and is provided inside the first rotating shaft 141 and the lower rotating body portion 120 while being provided on the outside of the first rotating shaft 141 ) To the first motor 142, the first small spiral portion 143 protruding in a small pitch spiral to the outer surface of the first rotating shaft 141, and the first small spiral portion 143 Consists of a first large helix portion 144 that is provided in succession and protrudes in a spiral with a larger pitch than this,

The second agitator 150 penetrates the lower body portion 120 and is provided inside the second rotating shaft 151 and the second rotating shaft 151 while being provided outside the lower body portion 120. ) Is connected to the second motor 152 driving the second small spiral portion 153 and the second small spiral portion 153 protruding in a small pitch spiral to the outer surface of the second rotating shaft 151 It is provided and consists of a second large spiral portion 154 projecting in a spiral with a pitch greater than this.

The twin spiral steam dryer 100 configured as described above passes through the upper body portion 110 by introducing sludge into the second inlet 112 and a catalyst (lime and hydrogen peroxide) through the first inlet 111. The lower body portion 120 is accommodated inside.

Subsequently, when the first agitator 140 and the second agitator 150 are rotated by driving the first motor 142 and the second motor 152, the first rotating shaft 141 and the first As the two coaxial shafts 151 are rotated, the first small spiral portion 143 and the first large spiral portion 144 and the second small spiral portion 153 and the second big spirally provided on the outer surface thereof are rotated, respectively. As the spiral portion 154 is rotated, the sludges stored in the lower body portion 120 are mixed with each other and mixed (stirred) to disperse them into small particles that are easy to heat transfer.

On the outer surface of the lower body portion 120 of the present invention, a plurality of heater plates 160 for generating heat are installed.

The heater plate 160 has a plate shape so that it can be mounted on the outer surface of the lower body portion 120 so that maintenance is good, and a heater wire is inserted into the inner surface in a zigzag manner to supply power. It is installed to indirectly heat the lower body portion 120 by installing to be heated by.

As described above, a catalyst (such as lime and hydrogen peroxide) is injected into the first inlet 111 to the second inlet 112 to supply the sludge to the inside of the lower body 120 and through the agitator 130. When these are stirred, the sludge and the catalyst are mixed with each other and chemical reactions occur and rise above a certain temperature.

At the same time, when the lower body part 120 is indirectly heated through the heater plate 160, the temperature inside the lower body part 120 rises rapidly, and drying of the sludge is easily achieved. A large amount of moisture is generated inside the body 120. The moisture generated inside the lower body portion 120 is discharged to the outside through a passage described later.

The lower body insulation portion 170 is installed outside the lower body portion 120 of the present invention to be spaced apart from the heater plate 160 to prevent the heating temperature of the lower body portion 120 from escaping to the outside. Is installed.

Therefore, most of the energy that is heated through the heater plate 160 can be transferred to the inside of the lower body portion 120 by the lower body insulating portion 170, so the loss energy to the outside is minimized and heating costs are minimized. Can save.

On the other hand, the first small spiral portion 143 and the first large spiral portion 144 of a small pitch provided on the outer surface of the first rotating shaft 141 of the first agitator 140, respectively, the first Two spiral protrusions G protrude so as to face each other toward the outside of the single coaxial shaft 141 so as to be spiral.

Likewise,

The small pitch second small spiral portion 153 and the second large spiral portion 154 provided on the outer surface of the second rotating shaft 151 of the second agitator 150 are respectively the second rotating shaft. The two spiral protrusions (G) protrude so as to face each other toward the outside of (151) so as to be spiral. In addition, the present invention, as shown in Figures 2 and 3, the first small helix portion 143 having a small pitch and the first large helix portion 144 having a large pitch is different in size from one side of the spiral blade and the other side Spiral blades are installed opposite each other, each consisting of a pair. Here, in the first pivot shaft 141, the first end of the spiral blade 141 has a small pitch, and both ends of the spiral blade are spaced apart at regular intervals from the first pivot shaft 141 to form a continuous spiral. A small connecting rod, and both ends of the other spiral blade of the first small spiral portion 143 are spaced apart from the first pivot shaft 141 at regular intervals to be continuously formed to form a spiral, but a second having a height greater than the first small connecting rod. A large connecting rod is provided. Also In the first pivot shaft 141, both sides of the spiral blade on one side of the first pitch spiral section 144 having a large pitch are spaced apart at regular intervals from the first pivot shaft 141, and are formed to form a third spiral continuously. The connecting rod and the other end of the other spiral blade of the first large spiral portion 144 are spaced apart from the first pivot shaft 141 to form a continuous spiral, but the fourth small connecting rod having a smaller height than the third larger connecting rod Is equipped. In addition, the second small helix portion 153 of the small pitch and the second large helix portion 154 of the large pitch are constituted by a pair of one side spiral blades and the other side spiral blades having different sizes, respectively. Here, in the second pivot shaft 151, a fifth pitch is installed such that both ends of one side of the spiral blade 153 of the small pitch second spiral portion 153 are spaced apart at regular intervals from the second pivot shaft 151. A small connecting rod, and both ends of the other side spiral blades of the second small spiral portion 153 are installed to form a continuous spiral at regular intervals from the second pivot shaft 151, but are sixth in height higher than the fifth small connecting rod. There is a large connecting rod. In addition, on the second pivot shaft 151, both sides of the one side of the spiral blades of the second large spiral section 154 are spaced apart at regular intervals from the second pivot shaft 151 to form a seventh large connecting rod. And the other end of the other side of the spiral blade wing of the second large helix portion 154 is installed to form a continuous spiral spaced apart at a certain interval from the second coaxial shaft 151, the eighth small connecting rod is smaller than the seventh large connecting rod Equipped At this time, the second large heat band, the third large heat band, the sixth large connecting rod and the seventh large tropical column have the same height, the first small connecting rod, the fourth small connecting rod, the fifth small connecting rod, and the eighth small connecting rod It has the same height.

In the present invention, the pitch is defined as a straight gap from the start to the end of the spiral projection projecting outside the rotational shaft. In general, the pitch of a screw is a distance between a mountain of a screw and a mountain, which is a straight line spacing in which the spiral is rotated 360 degrees or more, but in the present invention, the spacing between the start point and the end point where the spiral protrusion G is spirally formed as shown in the figure ( L1 to L4).

In addition, the pitch (L1) of the first small helix portion 143 and the pitch (L2) of the first large helix portion 144 are in a ratio of 1:2, and the second small helix portion 153 The pitch (L3) and the pitch (L2) of the second large spiral portion 154 are also provided at a ratio of 1:2.

In addition, the first small helical portion 143 provided in the first stirrer 140 and the second small helical portion 153 provided in the second stirrer 150 are diagonally opposed to each other and installed. The first large helix portion 144 provided in the first agitator 140 and the second large helix portion 154 provided in the second agitator 150 are also installed diagonally opposite each other.

The first stirrer 140 and the second stirrer 150 configured as described above, as shown in Figure 5 (b), the sludge flows into the inside of the lower body portion 120, the first Each of the motor 142 and the second motor 152 rotates in different directions (opposite directions).

At this time, the sludge is mixed while moving to the first large spiral portion 144 along the first small spiral portion 143 (this movement is referred to as convection or convection mixing) as shown in the direction of the arrow, and the first large spiral portion is mixed. The sludge moving to (144) is passed back to the second small spiral portion 153 and mixed (this is called vortex or vortex mixing), and then the second small spiral portion 153 is the sludge to the second large Moving (convection) to the spiral portion 154, the second large spiral portion 154 is passed through the sludge back to the first small spiral portion 143, the mixing cycle of convection and vortex mixing is repeatedly performed to the sludge Agitation is performed, and at the same time, the lower body portion 120 is heated by the heater plate 160 to dry the sludge.

Due to this, a large amount of steam is generated inside the lower body portion 120.

In the present invention, the first stirrer 140 and the second stirrer 150 are rotated in opposite directions inside the lower body portion 120 to cause the sludge to stir while causing convection and vortex. In this case, the sludge is stirred. As they collide with each other, they may fall to the lower portion of the central part and clump together (fixation).

The present invention is to prevent this phenomenon to more effectively perform the agitation of the sludge on the lower side between the first agitator 140 and the second agitator 150, the inner central lower side of the lower body portion 120. A third agitator 180 consisting of a third rotating shaft 181 rotated by a three-motor 181a and a third stirring blade 182 protruding from the outer peripheral surface of the third rotating shaft 181 is further installed. have.

Therefore, the surplus sludge that is not agitated by the rotation of the first stirrer 140 and the second stirrer 150 and falls to the bottom side while being agglomerated is transferred from the bottom side of the lower body portion 120 to the third stirrer 180. By stirring by the stirring efficiency of the sludge can be further improved.

In addition, a sludge discharge device 122 for discharging the dried sludge is provided on the bottom surface of the lower body portion 120. The sludge discharge device 122 is preferably composed of an actuator 122b operated by a motor 122a so that it can be opened and stored using electrical large force. This is because the sludge dried inside the lower body portion 120 has a large load and thus requires a large opening/closing force to open it while supporting it.

Therefore, when the drying of the sludge in the lower body part 120 is finished, the sludge discharge device 122 is opened to discharge the sludge dried in the lower body part 120. The discharged sludge is reused by landfilling or composting or fertilizing through a separate process.

In addition, the inner bottom surface of the lower body portion 120, as shown in Figure 4, after discharging the internal sludge through the sludge discharge device 122 to supply air or water to the inside to clean the injection port (123a) ) May be further provided with a plurality of piping portion 123.

Therefore, the sludge discharge device 122 is opened to discharge the dried sludge from the inside of the lower body part 120, and then supply air or water through the pipe part 123 by spraying it with the injection hole 123a. By cleaning the inside of the lower body portion 120 to remove the sludge debris and the like adhered to each stirrer to improve their durability.

On the other hand, the upper body portion 110 is formed inside the side wall and the upper surface so that they communicate with each other, the steam discharge passage 113 for discharging the steam generated inside the lower body portion 120 to the outside of the inflow It is equipped.

The steam discharge passage 113 includes a first passage 113a provided inside one wall surface of the upper body part 110 and a second passage 113b provided inside the upper wall surface of the upper body part 110, and They are made of a third passage 113c provided inside the other side of the wall of the upper body 110, and they communicate with each other, and the entrance of the first passage 113a communicates with the inside of the lower body 120. A first fan 114 for discharging steam is installed at the inlet, and an end portion of the third passage 113c communicates with the outside, and a second fan 115 for discharging steam is installed at the end.

This configuration allows the steam generated in the lower body part 120 to be cooled while being circulated through the steam discharge passage 113, thereby cooling the inside of the upper body part 110 by external air. Some parts are blocked. This is to prevent the inside of the upper body portion 110 from being cooled by outside air, thereby preventing the temperature of the inside from falling through the upper surface of the lower body portion 120 to improve drying efficiency.

In this way, the steam discharge passage 113 can reduce heating costs by reusing the internal heat (steam) generated in the lower body portion 120 to the upper body portion 110.

Here, the steam discharge passage 113 may be installed in the inner space portion of the upper body portion 110, and the first passage 113a may be installed at a predetermined interval and spaced apart.

In addition, the second passage 113b is formed in a zigzag shape inside the upper wall surface of the upper body portion 110 to delay the flow of steam passing through it, so that more steam heat is generated in the upper body portion 110. To be delivered to.

Inside the upper body portion 110,'b' shaped heater rod 116 may be further installed.

Therefore, according to the present invention, heat is additionally generated inside the upper body 110 through the heater rod 116 so that the internal temperature of the lower body 120 does not drop.

A drain pipe 117 communicating with the first passage 113a and discharging condensate generated in the steam discharge passage 113 to the outside is installed at a lower side of the upper body 110.

The steam discharge passage 113 generates condensed water due to a large temperature difference between the inside and outside as the steam generated inside the lower body part 120 passes, and the condensed water is periodically discharged through the drain pipe 117 To smooth the flow of steam.

In addition, the inner body of the upper body portion 110 is further provided with a connector 118 in communication with the first passage 113a to discharge internal heat and moisture.

In addition, an insulating material (not shown) may be further installed on the outside of the upper body portion 110 of the present invention to more effectively prevent the upper body portion 110 from being cooled.

The sludge or catalyst supplied to the first and second inlets 111 and 112 installed in the upper body portion 110 of the present invention is supplied through a conveying means such as a separate conveyor device (not shown).

As described above, the twin spiral steam dryer according to the present invention has dual upper and lower body spaces to supply sludge containing moisture to the lower body space part through the upper body space part, and is installed by replacing the lower body space part with left and right sides. A pair of spiral stirrers are rotated in opposite directions to agitate the stored sludge, and at the same time, the sludge is dried by applying heat to the inside through a heater installed on the outer surface of the lower body space, and the steam generated during drying is upper It is designed to minimize the heat loss of the upper body space while discharging to the outside through the space provided at the edge of the body space, thereby dramatically improving the drying efficiency of the sludge.

100: twin spiral steam dryer
110: upper body
111: 1st entrance 112: 2nd entrance 113: Steam discharge passage
113a: First passage 113b: Second passage 113c: Third passage 114: First fan 115: Second fan
116: heater rod 117: drain piping 118: connector
120: lower body
121: support 122: sludge discharge device 122a: motor 122b: actuator
123: piping section 123a: injection port
130: agitator
140: first agitator
141: 1st coaxial 142: 1st motor 143: 1st small screw part 144: 1st large screw part
150: Second agitator
151: 2nd coaxial 152: 2nd motor 153: 2nd small screw part 154: 2nd large screw part
160: Heater plate
170: lower body insulation
180: third agitator
181: 3rd coaxial 181a: 3rd motor 182: 3rd stirring blade G: Spiral projection

Claims (9)

An upper body portion 110 provided with an inlet for supplying sludge containing moisture and a catalyst to the upper side and having a hollow inside;
A lower body portion 120 in which a sludge storage space is formed therein while being continuously provided on a lower surface of the upper body portion 110;
The stirrer 130 is installed opposite to each other on the inner middle side of the lower body portion 120 and mixing (stirring) the sludge contained inside the lower body portion 120 while mixing and rotating them in opposite directions; Includes,
The stirrer 130 has a first stirrer 140 installed on one side of the middle of the lower body portion 120 and a second stirrer 150 symmetrically installed on the other side of the first stirrer 140. In pairs;
The first agitator 140 is provided on the outside of the first rotating shaft 141 and the lower body 120, the first motor 142 to drive the first rotating shaft 141, the first A first small spiral portion 143 protruding in a small pitch spiral to the outer surface of the rotating shaft 141, and the first small shaft 143, which is provided in succession to the first small spiral portion 143, and has a larger pitch spiral. It includes a first large spiral portion 144 protruding from the outer surface of (141); The second agitator 150 is provided on the outside of the second rotating shaft 151 and the lower body portion 120, a second motor 152 driving the second rotating shaft 151, the second A second small spiral portion 153 protruding in a spiral with a small pitch on the outer surface of the rotating shaft 151, and a second spiral shaft in a spiral with a pitch larger than that provided in succession to the second small spiral portion 153 It includes a second large spiral portion 154 protruding from the outer surface of (151),
The outer surface of the lower body portion 120 is in contact with the outer surface of the lower side of the lower body portion 120, a plurality of heater plates 160 for heating and supplying heat to the interior of the lower body portion 120 ) Is installed;

The first small spiral section 143 of the small pitch and the first large spiral section 144 of the large pitch are configured with a pair of one side spiral blades and the other side spiral blades of different sizes installed opposite each other,
In the first coaxial 141,
The first small connecting rod and the first small spiral unit (140) are installed such that both ends of the one side spiral blade of the small pitch first small spiral unit 143 are spaced apart at regular intervals from the first pivot shaft 141 and continuously spiral. 143) the other end of the other side of the spiral blade is installed to form a spiral continuously spaced apart at a predetermined interval from the first shaft 141, the second large connecting rod of a height greater than the first small connecting rod;
A third large connecting rod that is installed to form a continuous spiral while both sides of one side of the first large spiral portion 144 of a large pitch are spaced apart at a predetermined interval from the first pivot shaft 141, and the first big spiral portion ( 144) the other end of the other side of the spiral blade is installed to form a continuous spiral spaced apart at a predetermined interval from the first pivot (141), but is provided with a fourth small connecting rod smaller than the third large connecting rod,

The second small helix portion 153 of the small pitch and the second large helix portion 154 of the large pitch are configured with a pair of one side spiral blades and the other side spiral blades of different sizes installed opposite each other,
On the second coaxial (151),
The fifth small connecting rod and the second small spiral unit (102) are installed so that both ends of one side of the small-wing second small spiral unit 153 are spaced apart at regular intervals from the second pivot shaft 151, and the second small spiral unit (153) 153) the other end of the other side of the spiral blade is installed to form a continuous spiral spaced apart at a predetermined interval from the second pivot shaft 151, the sixth large connecting rod with a height greater than the fifth small connecting rod;
The seventh large connecting rod is installed so that one side of the spiral blades of the second large spiral portion 154 of a large pitch is spaced apart at regular intervals from the second pivot shaft 151, and the second large spiral portion ( 154) twin spiral steam dryers having both ends of the other side of the spiral wing are installed to form a continuous spiral while being spaced apart from the second pivot shaft 151 at regular intervals, but with an eighth smaller connecting rod smaller than the seventh largest connecting rod.
delete According to claim 1,
The first small spiral portion 143 and the first large spiral portion 144 of a small pitch provided on the outer surface of the first rotating shaft 141 of the first agitator 140 are respectively the first time Two spiral protrusions (G) to the outside of the coaxial (141) are installed so as to protrude while facing each other to become a spiral,
The small pitch second small spiral portion 153 and the second large spiral portion 154 provided on the outer surface of the second rotating shaft 151 of the second agitator 150 are respectively the second rotating shaft. The twin spiral steam dryer is installed so that the two spiral protrusions (G) protrude while facing each other to the outside of (151).
According to claim 3,
The pitch L1 of the first small helix 143 and the pitch L2 of the first large helix 144 are in a ratio of 1:2, and the pitch L3 of the second small helix 153 ) And the pitch (L2) of the second large spiral portion 154 is also composed of a ratio of 1:2 twin spiral steam dryer.
According to claim 4,
The first small spiral part 143 provided in the first agitator 140 and the second small spiral part 153 provided in the second agitator 150 are installed diagonally opposite each other, and the first The first large spiral unit 144 provided in the first stirrer 140 and the second large spiral unit 154 provided in the second stirrer 150 are also installed diagonally opposite to each other in a twin spiral steam dryer.
According to claim 3,
On the lower side between the first agitator 140 and the second agitator 150, which is an inner central lower side of the lower body portion 120, a third rotation shaft 181 rotated by a third motor 181a A twin spiral steam dryer further comprising a third agitator (180) consisting of a third agitator blade (182) protruding from the outer circumferential surface of the third coaxial shaft (181).
According to claim 1,
The upper body portion 110 is formed inside the side wall and the upper surface, they are in communication with each other, and a steam discharge passage 113 is provided for circulating steam generated inside the lower body portion 120 and discharging it to the outside. Twin spiral steam dryer.
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