TWM508549U - Pipeline-type sludge drying device - Google Patents

Description

Pipeline type sludge drying device

The present invention relates to a drying device, and more particularly to a sludge drying device.

Referring to FIGS. 1 and 2 , a sludge drying device 1 includes a mixing drum 11 , a heating and stirring unit 12 , a casing member 13 , an air extracting unit 14 , and a driving unit 15 . The mixing drum 11 includes a barrel wall 111 defining an agitation space 110 around an axis L, and an inlet port 112 and a discharge joint 113 spaced apart from the barrel wall 111 and communicating with the agitation space. The heating and agitating unit 12 includes a mandrel 121 rotatably disposed along the axis L and having an axial through hole 120, and a plurality of pairs extending radially outward from the mandrel 121 and along the axis The agitating plates 122 spaced apart from each other in the agitation space 110, and a hot gas pipe 123 penetrating the agitating plates 122 and communicating with the axial through holes 120 of the mandrel 121. The outer casing member 13 is disposed on the outer circumferential surface of the agitating drum 11 and cooperates with the agitating drum 11 to define a plurality of heating spaces 130 located therebetween. The air extraction unit 14 communicates with the agitation space 110. The driving unit 15 is connected to one end of the mandrel 121 for driving the heating and stirring unit 12 to rotate. The axial through hole 120 of the mandrel 121 is connected to the heating space 130 by a pipeline unit 16 connected to a heating unit 17.

When the sludge drying device 1 performs sludge drying, the sludge which can be dried once by the sludge drying device 1 is firstly fed into the agitation space 110 from the inlet port 112, and then the heating is started. The unit 17 and a heat medium are conveyed into the heating space 130, the axial through hole 120 and the heating pipe 123 via the pipeline unit 16, so that the stirring space 110 is heated by the inside and outside of the mixing drum 11, and then the driving is started. The unit 15 drives the heating and agitating unit 12 to rotate, and the agitating plates 122 are linked to agitate the sludge, and the pumping unit 14 is turned on. During the sludge agitation process, the sludge absorbs the heat of the heat medium to evaporate the water content. The evaporated water is further withdrawn from the agitation space 110 via the pumping unit 14, and after the sludge is dried to a certain humidity or less over a period of time, the dried sludge can be removed through the discharge joint 123 for subsequent processing.

However, the sludge drying device 1 described above can dry the sludge, but has the following disadvantages in use:

1. Each pair of stirring plates 122 rotates the agitated sludge at a fixed point, and the effect of pushing the sludge in the axial direction is limited, so that the sludge is easily accumulated in two pairs of adjacent stirring plates 122 to form a large volume of sludge. However, the drying speed of the large-volume sludge mass is obviously slower than that of the dispersed sludge, thus causing the drying efficiency of the sludge drying device 1 to be low. In addition, the un-dispersed sludge mass gradually becomes dry and is easily formed into a wet inner sludge block. However, the agitating plates 122 can have a limited effect of stirring and dispersing the sludge hard block, thereby causing the same batch of drying treatment. There is also a sludge lumps with high humidity in the sludge.

Second, because the mixing drum 11 is large in volume, the heating stirring single The agitating plates 122 of the element 12 also need a sufficient length to effectively agitate the sludge, thereby increasing the rotational inertia of the heating agitating unit 12 as a whole, so that the driving unit 15 requires a large power to drive the heating agitating unit 12 to rotate. Thereby increasing energy consumption. In addition, the large volume of the mixing drum 11 also causes the inner wall surface of the barrel wall 111 heated by the heated medium to become high, and the heat radiation distance for heating the stirring space 110 becomes large, which is liable to cause thermal energy loss. Therefore, it is necessary to accelerate the circulation of the heat medium to maintain the radiation to The heat energy in the agitation space 110 is unbalanced, thereby increasing energy consumption.

3. The sludge drying device 1 is configured to batch-deliver the sludge into the agitation space 110 of the agitating drum 11 for drying treatment, and then dry the sludge to be removed from the agitation space 110, thus requiring additional manpower. Each batch of the sludge to be dried is fed into and out of the agitation space 110 of the agitating drum 11.

Therefore, the object of the present invention is to provide a line type sludge drying device which is effective in energy saving, high in drying efficiency, and capable of continuously treating sludge.

Therefore, the novel pipeline type sludge drying device comprises a pipe unit, a heating unit, a stirring unit, a driving unit, and a pumping unit.

The pipe unit comprises a pipe member defining an agitation space around an axis, two end caps respectively disposed at opposite ends of the pipe member, and an inlet and outlet joint group and a pumping pipe which are disposed in the pipe member and communicate with the agitation space. Connector set. The inlet and outlet joint sets have at least one feed joint and one discharge joint respectively located at opposite ends of the tubular member.

The heating unit is coupled to the tube unit and can supply heat to the tube.

The agitating unit comprises two shaft seats respectively pivoted on the end caps, and a stirring group extending along the axis and connected between the shaft seats. The mixing group has a spirally-cut long plate, a plurality of stirring columns and a plurality of scraping bars. The helically-cut long plate is helical about the axis and has a radially outer side spaced radially adjacent to the inner wall surface of the tubular member and a helical inner side adjacent the axis. The agitating columns are spaced apart from the axis to the inner side of the spiral. The scrapers are spaced apart from the axis and extend along the axis and extend along the axis, and each has a scraping surface that is aligned with the outer side of the spiral of the auger.

The driving unit is coupled to one of the equipotential seats for driving the agitation unit to rotate.

The air suction unit is connected to the air suction joint group for extracting air and water vapor in the agitation space.

The utility model has the following effects: when the stirring unit rotates, the spiral pushing and cutting long board can cut and split the sludge roll, and pushes the broken sludge in the axial direction toward the discharge joint, and the same The stirring column is used to pulverize the sludge in a circular motion, and the scraping rod scrapes the scattered sludge on the inner wall surface of the inner wall of the high temperature for direct heating and then scraping, thereby stirring The unit can effectively agitate the sludge to avoid agglomeration, thereby accelerating the drying speed of the sludge.

2‧‧‧Fitting unit

20‧‧‧Spiring space

21‧‧‧ Pipe fittings

210‧‧‧heating space

211‧‧‧ inner wall

212‧‧‧ outer wall

22‧‧‧End cover

23‧‧‧Incoming and outgoing joint group

231‧‧‧Feed connector

232‧‧‧Drain connector

24‧‧‧Exhaust joint group

241‧‧‧Exhaust joint

25‧‧‧heating joint group

251‧‧‧Input connector

252‧‧‧Output connector

3‧‧‧Stirring unit

31‧‧‧ shaft seat

32‧‧‧ mixing group

321‧‧‧Spiral cutting longboard

322‧‧‧ stir column

323‧‧‧Shaper

324‧‧‧Spiral outer side

325‧‧‧Spiral inside

326‧‧‧Scratch the face

4‧‧‧ drive unit

41‧‧‧ Gear seat

42‧‧‧Motor

421‧‧‧ Output pinion

43‧‧‧Chain

5‧‧‧heating unit

6‧‧‧Pumping unit

7‧‧‧Insulation unit

71‧‧‧Insulation cotton layer

72‧‧‧Covering parts

81‧‧‧Sludge automatic quantitative feeding device

82‧‧‧Dry sludge storage tank

9‧‧‧Line type sludge drying device

L‧‧‧ axis

Other features and effects of the present invention will be apparent from the detailed description of the preferred embodiments of the drawings. Figure 1 is a schematic side view of a conventional sludge drying device; Figure 2 is a partial cross-sectional view of the sludge drying device; Figure 3 is a partial cross-sectional view of an embodiment of the present invention; FIG. 4 is a cross-sectional view of the embodiment in the radial direction; Figure 5 is a partial cross-sectional view of the embodiment in the axial direction; Figure 6 is a partial cross-sectional view of the two-stage pipeline type sludge drying device assembled with two stacks; Figure 7 is a top plan view showing two The pipeline type sludge drying device assembled together may also be displaced at a rotation angle θ; Figure 8 is a side elevational view showing the two line-type sludge drying devices assembled together may also be offset at an oblique angle φ.

Referring to FIG. 3, FIG. 4 and FIG. 5, an embodiment of the pipeline type sludge drying device 9 of the present invention comprises a pipe unit 2, a stirring unit 3, a driving unit 4, a heating unit 5, and a pumping unit. 6, and a thermal insulation unit 7.

The pipe unit 2 includes a pipe member 21 defining an agitation space 20 around an axis L, two end caps 22 respectively disposed at opposite ends of the pipe member 21, an inlet and outlet joint group 23, and an air suction joint group 24, and A heat supply connector set 25. The tube member 21 has an inner tube wall 211 and an outer tube wall 212 spaced apart in the radial direction, and a heating space 210 formed between the inner tube wall 211 and the outer tube wall 212.

The inlet and outlet joint group 23 is radially disposed on the outer tube wall 212 The inner tube wall 211 is connected and communicates with the agitation space 20, and has three inlet joints 231 located at one end of the tube member 21 and a discharge joint 232 located at the other end of the tube member 21. In use, the feed joints 231 are connected to a sludge automatic dosing device 81 which receives a dry sludge storage tank 82. The air suction joint group 24 has two air suction joints 241 that are disposed to penetrate the outer pipe wall 212 in the radial direction to connect the inner pipe wall 211 and communicate with the agitation space 210. The heating joint set 25 has an input joint 251 and an output joint 252 which are respectively disposed at opposite ends of the outer tube wall 212 and communicate with the heating space 210. It is worth mentioning that the number of the feed joints 231 of the inlet and outlet joint group 23 is not limited to the above, and may be only one or other quantities, and the number of the suction joints 241 of the suction joint group 24 is not The above is limited to one or only other quantities. In this embodiment, the inner diameter, the outer diameter and the length of the pipe member 21 are 20 cm, 30 cm and 6 m, respectively, but the inner diameter or outer diameter of the pipe member 21 can be processed according to the sludge throughput. The size can be varied from 10 cm to 60 cm, and the length can be changed from 2 meters to 10 meters.

The agitating unit 3 includes two shaft seats 31 respectively axially disposed on the end caps 22, and a stirring group 32 extending along the axis L and connected between the shaft seats 31. The agitating group 32 has a spirally-cut long plate 321 , three stirring columns 322 and three scraping rods 323 . The spiral-pushing long plates 321 are spiral around the axis L and have a radially spaced one immediately adjacent to the inner tube. The spiral outer side surface 324 of the inner wall surface of the wall 211 and a spiral inner side surface 325 adjacent to the axis L are disposed on the spiral inner side surface 325 around the axis L. The scrapers 323 are spaced around the axis L to be inserted into the spiral The long plate 321 has a scraping surface 326 which is aligned with the spiral outer side surface 325 of the spirally-cut long plate 321 . It is worth mentioning that the number of the stirring column 322 and the scraping rod 323 of the stirring group 32 is not limited to the above.

The driving unit 4 is connected to one of the equipotential seats 31 for driving the stirring unit 2 to rotate. In this embodiment, the driving unit 4 has a gear base 41 mounted on the shaft base 31, a motor 42, and a chain 43 connecting the gear base 41 and the output pinion 421 of the motor 42. The motor 42 is driven by the chain 43 to drive the gear base 41 to rotate, so that the agitation unit 2 rotates with the gear base 42. However, the driving unit 4 drives the stirring unit 2 to rotate in a manner not limited to the above, and may be driven in other manners. For example, the driving unit 4 directly drives the shaft base 31 by an output shaft (not shown) of a motor. The stirring unit 2 is rotated.

The heating unit 5 is connected to the heating joint group 25, and the heating unit 5 can input a hot medium (not shown) having a high temperature after heating, such as heat medium oil or steam, into the flow through the input joint 251. The inner tube wall 211 is heated in the heating space 210, so that the inner tube wall 211 having a high temperature is heated to the stirring space 20 by heat radiation, and finally the lower temperature heat medium is replaced by the heat medium. The output connector 252 flows back to the heating unit 5 for reheating and reuse.

The air extraction unit 6 is connected to the air suction joints 241, and the air suction units 6 can extract the gas in the agitation space 20. In the present embodiment, the pumping unit 6 is a vacuum pump.

The heat preservation unit 7 is configured to prevent heat energy from being dissipated outward from the pipe member 21, thereby achieving the effect of heat preservation and energy saving, and preventing the person from touching the high temperature. The tube 21 is burnt. The thermal insulation unit 7 includes a thermal insulation cotton layer 71 surrounding the outer wall surface of the outer tubular wall 212 of the tubular member 21, and a cover insulating layer 71 is attached to the outer surface of the thermal insulation cotton layer 71 to fix the thermal insulation cotton layer 71 to the tubular member 21. The cover member 72 is covered.

The above is the description of the component composition of the new pipeline type sludge drying device 9; then, the use action of the present invention and the expected effect can be stated as follows:

When the sludge drying is performed by the pipeline type sludge drying device 9 of the present invention, the heating unit 5 is first turned on to circulate the heat medium to the heating space 210 to heat the stirring space 20, and then the driving unit 4 is started to be driven. The agitation unit 2 is rotated, and the pumping unit 6 is opened, and the sludge is sent into the agitation space 20 by the automatic sludge feeding device 81 via the feed joints 231. When the agitation unit 2 is rotating, The spiral push-cut long plate 321 spiraling around the axis L cuts the sludge roll and pushes the broken sludge axially toward the discharge joint 232. The stirring column 322 is smooth. The circular motion pulverizes and disperses the sludge, and the scraper 323 scrapes the dispersed sludge onto the inner wall of the inner wall 211 having a high temperature for direct heating and then scrapes off, thereby accelerating the drying of the sludge. At the speed, during the agitation and heating of the sludge, the agitation unit 6 draws the mixed gas of the water vapor and the organic solvent gas evaporated by the sludge containing the thermal energy of the sludge into the agitation space 20, and conducts it to the agitating space 20 Burning inside the boiler (not shown) to avoid The humidity in the stirring space 20 is too high, which affects the drying speed of the sludge, and achieves deodorization and avoids the leakage of the organic solvent gas to the atmosphere, and finally the sludge which is gradually dried to below one humidity is moved by the stirring unit 2 to The discharge joint 232 is discharged to the dry sludge storage tank 82 via the discharge joint 232 for storage.

It is worth mentioning that when the overall length of the pipeline type sludge drying device 9 is designed to be long, or the stirring unit 2 rotates faster and the sludge speed is relatively fast, the heating unit can be controlled. 5 The flow direction of circulating the hot medium in the heating space 210 is adjusted to be opposite to the direction in which the stirring unit 2 rotates and pushes the sludge to achieve an optimal heat transfer effect, thereby improving drying efficiency and thereby effectively saving energy.

It is worth mentioning that, because the new pipeline type sludge drying device 9 is tubular and small in size, two or more of the new pipeline type sludge drying devices 9 can be assembled according to the actual needs of different sludge amounts. (See Fig. 6), the series or parallel expansion is performed to process the increased amount of sludge to be treated, and the assembly relationship of the pipeline type sludge drying device 9 is not limited to the parallel stack assembly method shown in Fig. 6. Alternatively, the two-phase connected line type sludge drying device 9 shown in FIG. 7 may be displaced at a rotation angle θ, or may be a two-phase connected line type sludge drying device 9 as shown in FIG. If the inclination angle φ is misaligned, the line type sludge drying device 9 can be arbitrarily combined in combination with the above-described assembly method, thereby conforming to the space arrangement of the building for mounting the line type sludge drying device 9, and thereby The installation position of the inlet type joint 231 connected to the automatic sludge dosing device 81 and the discharge joint 232 corresponding to the dry sludge storage tank 82 can be arbitrarily set without limitation. Adjustment to facilitate sludge transport Subsequent transportation processing and subsequent transportation processing after drying sludge discharge.

According to the above description, the new pipeline type sludge drying device is known. Setting 9 has the following advantages and effects:

1. When the stirring unit 3 rotates, the spiral pushing and cutting long plate 321 cuts and breaks the sludge roll, and pushes the broken sludge in the axial direction toward the discharging joint 232, and the stirring column 322 The sludge is pulverized and dispersed according to the circular motion, and the scraper 323 scrapes the scattered sludge on the inner wall surface of the inner wall 211 having a high temperature for direct heating and then scraping, thereby stirring Unit 3 can effectively disperse the sludge to avoid agglomeration, thereby accelerating the drying speed of the sludge.

2. Since the pipe diameter of the pipe member 21 is much smaller than the barrel diameter of the conventional mixing drum, the heat radiation distance between the inner wall surface of the inner pipe wall 211 and the sludge which is high after heating is shorter than that of the conventional mixing drum, and the dirt can be contaminated. The mud receives the heat more quickly and the water is rapidly evaporated, and the shorter the heat radiation distance, the less heat energy is transferred, thereby effectively reducing energy consumption.

3. Since the pipe diameter of the pipe member 21 is small, the outer diameter of the agitation group 32 disposed therein is also relatively small, so the moment of inertia of the agitation group 32 is relatively small, so that the drive unit 4 requires only a small amount of power. The stirring of the stirring unit 3 is driven to achieve a sludge tumbling effect, which greatly reduces the power demand.

4. The agitating unit 3 can continuously push the sludge fed into the agitation space 20 by the feeding joints 231, and continuously push the sludge to the discharge joint 232 to discharge to the dry sludge storage tank 82, so that only The slurry can be continuously supplied to the sludge through the sludge automatic dosing device 81, and the present invention can automatically perform the sludge drying operation continuously, compared with the conventional sludge drying device which can only perform sludge drying treatment in batches. Significant savings in manpower requirements.

5. Due to the volume of the new pipeline type sludge drying device 9 Small, according to the actual demand of sludge drying, the combination of two or more series in series or in parallel can be used to effectively save the additional cost of sludge drying equipment. In addition, the small-sized pipeline type sludge drying device 9 has a small space and takes up a small space, and can effectively save the construction cost of accommodating the building.

However, the above is only a preferred embodiment of the present invention, and when it is not possible to limit the scope of the present invention, any simple equivalent changes and modifications made in accordance with the scope of the present patent application and the contents of the patent specification are It is still within the scope of this new patent.

2‧‧‧Fitting unit

20‧‧‧Spiring space

21‧‧‧ Pipe fittings

210‧‧‧heating space

211‧‧‧ inner wall

212‧‧‧ outer wall

22‧‧‧End cover

23‧‧‧Incoming and outgoing joint group

231‧‧‧Feed connector

232‧‧‧Drain connector

24‧‧‧Exhaust joint group

241‧‧‧Exhaust joint

25‧‧‧heating joint group

251‧‧‧Input connector

252‧‧‧Output connector

3‧‧‧Stirring unit

31‧‧‧ shaft seat

32‧‧‧ mixing group

321‧‧‧Spiral cutting longboard

322‧‧‧ stir column

323‧‧‧Shaper

324‧‧‧Spiral outer side

325‧‧‧Spiral inside

4‧‧‧ drive unit

41‧‧‧ Gear seat

42‧‧‧Motor

421‧‧‧ Output pinion

43‧‧‧Chain

5‧‧‧heating unit

6‧‧‧Pumping unit

7‧‧‧Insulation unit

71‧‧‧Insulation cotton layer

72‧‧‧Covering parts

81‧‧‧Sludge automatic quantitative feeding device

82‧‧‧Dry sludge storage tank

9‧‧‧Line type sludge drying device

L‧‧‧ axis

Claims (5)

A pipeline type sludge drying device comprises: a pipe unit comprising a pipe member defining an agitation space around an axis, two end caps respectively disposed at opposite ends of the pipe member, and being disposed through the pipe member and communicating the agitation An inlet and outlet joint group and a suction joint group of the space, the inlet and outlet joint group having at least one feed joint and one discharge joint respectively located at opposite ends of the pipe; a heat supply unit connecting the pipe unit Heating the tube; a stirring unit comprising two shaft bases respectively pivoted on the end caps, and a stirring group extending along the axis and connected between the shaft seats, the stirring group having a spiral cutting a long plate, a plurality of agitating columns and a plurality of scraping rods, the spirally elongating plate is helical about the axis and has a radially outer side spaced apart from the inner wall surface of the tubular member and a spiral inner side adjacent to the axis The agitating columns are disposed on the inner side of the spiral around the axis, and the scraping rods are spaced around the axis and extend along the axis and extend along the axis, and have a screw and a screw respectively. a scraping surface of the spiral outer side of the long plate; a driving unit connecting one of the equipotential seats for driving the stirring unit to rotate; and a pumping unit connecting the pumping joint group for The gas in the agitation space is withdrawn. The pipeline type sludge drying device according to claim 1, further comprising an insulation unit, wherein the insulation unit includes an outer wall covering the outer tube wall The insulating cotton layer of the surface, and a covering shell member which is coated on the outer side of the insulating cotton layer to fix the insulating cotton layer on the pipe member. The pipeline type sludge drying device according to claim 1, wherein the pipe member has an inner pipe wall and an outer pipe wall spaced apart in the radial direction, and is formed between the inner pipe wall and the outer pipe wall. A heating space that communicates with the heating unit. The pipeline type sludge drying device according to claim 3, wherein the pipe unit further comprises a heat supply joint group connected to the heat supply unit, the heat supply joint group having opposite ends respectively disposed on the outer pipe wall And an input joint connecting the heating space and an output joint, wherein the heat supply unit can flow a heat medium into the heating space via the heat supply joint group. The pipeline type sludge drying device according to claim 1, wherein the driving unit has a gear base mounted to the shaft seat, a motor, and a chain connecting the gear base and an output pinion of the motor.