KR101387010B1 - Multi-pass dryer for waste material - Google Patents

Abstract

The present invention relates to a multi-pass dryer for waste materials that dries waste materials with high moisture contents, such as food waste and sludge, by supplying hot air while transporting the waste materials. The multi-pass dryer for waste materials according to the present invention includes a drying furnace that has a plurality of drying chambers which are partitioned by a plurality of partitioning walls; a plurality of drying chamber discharge paths that are provided to be respectively connected to the drying chambers; a plurality of hot air supply ducts that are arranged in the respective drying chambers in a direction in which the waste material is transported so as to transport the waste material with a plurality of injection holes formed to be spaced in the direction in which the waste material is transported; and one or more hot air supply devices that supply hot air to the hot air supply ducts. The multi-pass dryer for waste materials according to the present invention dries the waste material that flows through a waste material inlet provided in the drying furnace while the hot air is supplied and the waste material passes through the drying chambers one after another in a zigzag shape.

Description

Multi-pass dryer for waste material

The present invention relates to a multi-stage waste drying apparatus, and more particularly, to a multi-stage waste drying apparatus for supplying and drying hot air while transferring waste having a high moisture content such as food waste or sludge.

Recently, the amount of waste is increasing day by day due to industrial development and population increase. Waste causes environmental pollution, and useful resources contained therein are discarded. Therefore, it is important to efficiently treat and recover the waste.

Waste can be largely classified into domestic waste generated in the living environment and workplace waste generated in industrial sites. Workplace waste is classified into workplace general waste, workplace emission waste, workplace construction waste, and workplace designated waste, depending on the source. These can be classified into organic waste and inorganic waste in terms of the properties of the materials.

In general, organic waste includes food waste, livestock manure, servings, wastes from agricultural and aquatic product processing, wastes from food processing and waste from slaughterhouses. Such organic wastes have a high moisture content and high concentrations of pollutants discharged, and thus are difficult to treat.

Among these, incineration treatment requires a huge fuel cost, and incineration residues such as dust and dioxins generated during incineration cause secondary environmental pollution. In the case of landfill, it is difficult to secure a landfill site, and there is a problem in that surrounding soil and rivers are contaminated by leachate generated from waste. On the other hand, composting or foddering is a treatment method that can recycle wastes as a resource, and various studies have been conducted.

In order to recycle wastes with high water content as compost or feed, the first thing to do is to reduce the moisture in the wastes. Various kinds of waste drying apparatuses are currently proposed to rapidly reduce the moisture contained in the waste. Examples of waste drying apparatus include Korean Patent Application Publication No. 2006-0117617 (published on November 17, 2006), Korean Patent Publication No. 1612920 (registered on June 29, 2012), and Korean Patent Publication No. 1197302 (2012. 10. 29 registration).

However, in the conventional waste drying apparatus as described above, the waste is put into a rotating drum and heat is supplied to the drum to dry the waste. There is a problem in that the waste transport efficiency is low because the waste transport path is short. In order to increase the drying efficiency of the drum type waste drying apparatus, the length of the drying apparatus must be designed long or a high temperature hot air must be used. As a result, the risk of fire increases.

The present invention has been made in view of this point, and an object of the present invention is to arrange a plurality of drying chambers in multiple stages in the vertical direction and to move the wastes sequentially from the upper drying chamber to the lower drying chamber to lengthen the transportation path of the waste. It is to provide a multi-stage waste drying apparatus that can increase the drying efficiency.

Multi-stage waste drying apparatus according to the present invention for achieving the above object is a plurality of partition walls and waste installed in the inner space that can accommodate the waste and the inner space spaced vertically to partition the inner space into a plurality of drying chambers A drying furnace having a waste inlet connected to a drying chamber positioned at the top of the plurality of drying chambers for input of waste and a waste outlet connected to a drying chamber located at the bottom of the plurality of drying chambers for discharging dried waste; The plurality of drying chamber discharge paths are provided to be connected to each of the plurality of drying chambers so that the wastes introduced into each of the drying chambers are discharged from each of the plurality of drying chambers and move downward. To the drying chamber outlet connected to each of the drying chambers A plurality of waste conveying apparatus is installed in each of the plurality of drying chambers, and installed in the plurality of partition walls for introducing hot air into each of the plurality of drying chambers are disposed along each of the plurality of drying chambers along the conveying direction of waste, The plurality of injection holes for injecting hot air comprises a plurality of hot air supply ducts spaced apart along the conveying direction of the waste, and at least one hot air supply device for supplying hot air to the plurality of hot air supply ducts, the plurality of wastes A conveying apparatus is installed in each of the plurality of drying chambers so that the conveying direction of the wastes in two adjacent drying chambers among the plurality of drying chambers is opposite to each other, and the plurality of drying chamber discharge paths are respectively installed in the drying chambers to which they are connected. Disposed at the rear end, the waste flowing into the waste inlet This will be the plurality of the drying chamber, characterized in that in order to pass in a zigzag form discharged to the waste outlet.

A plurality of waste conveying apparatuses are installed per one drying chamber, and the hot air supply duct is disposed between the plurality of waste conveying apparatuses installed in one drying chamber, and the waste conveying apparatuses having spray nozzles provided thereon are disposed on both sides thereof. It may be provided in a double row to face.

Each of the plurality of waste conveying apparatuses may include a screw blade disposed between the rotary shaft and the front end of the rotary shaft so as to push the waste out, and a plurality of the waste shafts spaced between the rear end and the middle of the rotary shaft to crush waste. May comprise a grinding paddle.

The plurality of separation walls may be disposed to be inclined downward toward a drying chamber discharge path connected to the corresponding drying chamber.

The hot air supply device is connected to the hot air recovery pipe for centrifuging the air sucked into the hot air recovery pipe and at least one hot air recovery pipe connected to the inside of the drying furnace to suck the air inside the drying furnace. A centrifugal separator, a hot wind heater for heating the air passing through the centrifugal separator, a blower for blowing air heated by the hot wind heater, and at least one hot wind supply pipe connecting the blower and the plurality of hot wind supply ducts. It may include.

The hot air supply device may further include an external air heater for supplying the outside air heated by burning fuel to the hot air supply pipe.

The multi-stage waste drying apparatus according to the present invention is connected to the air suction pipe for centrifuging at least one air suction pipe connected to the inside of the drying furnace and the air sucked into the air suction pipe so as to suck the air inside the drying furnace. The apparatus may further include a deodorizer for burning and deodorizing the air passed through the centrifuge and an exhaust air processor including an exhaust pipe connected to the deodorizer to exhaust the air passing through the deodorizer to the outside.

The hot air supply device is provided with a plurality so as to be connected to the plurality of drying chambers in a one-to-one, each of the hot air supply device, a hot air recovery pipe connected to the drying chamber to suck the air of the drying chamber, and the hot air recovery A centrifugal separator connected to the hot air recovery pipe for centrifuging the air sucked into the pipe, a hot air heater for heating the air passing through the centrifugal separator, a blower for blowing the air heated in the hot air heater, It may include a hot air supply pipe for connecting the blower and the hot air supply duct installed in the drying chamber.

The hot air supply device is provided with a plurality of fewer than the plurality of drying chamber, each of the plurality of hot air supply device supplies hot air to at least two of the plurality of drying chamber, each of the hot air supply device, the corresponding drying chamber A plurality of hot air recovery tubes connected to the corresponding drying chambers to suck the air of the air, a centrifuge connected to the plurality of hot air recovery tubes for centrifuging the air sucked into the plurality of hot air recovery tubes, and the centrifugal separator It may include a hot air heater for heating the air passed through the separator, a blower for blowing the air heated in the hot air heater, and a plurality of hot air supply pipe connecting the blower and hot air supply ducts installed in the drying chambers. .

Each hot air supply device further comprises one or more external air mixers connected to one or more of the hot air supply pipes for mixing the outside air with the hot air supplied to the hot air supply ducts through the hot air supply pipes connected to the corresponding drying chambers. can do.

The hot air supply apparatus includes a plurality of hot air recovery tubes connected to some drying chambers of the plurality of drying chambers, and a centrifuge connected to the plurality of hot air recovery tubes for centrifuging the air sucked into the plurality of hot air recovery tubes. A hot air heater for heating the air passing through the centrifuge, a blower for blowing the air heated by the hot air heater, and a plurality of hot air supply pipes connecting the blower and hot air supply ducts installed in the plurality of drying chambers. It may include.

The multi-stage waste drying apparatus according to the present invention, for centrifuging the air sucked into the at least one air suction pipe and the one or more air suction pipe connected to the drying chamber in which the hot air recovery pipes of the hot air supply device is not connected among the plurality of drying chambers. A discharge air processor having a centrifugal separator connected to the at least one air suction pipe, a deodorizer for burning and deodorizing air passing through the centrifugal separator, and an exhaust pipe connected to the deodorizer for exhausting the air passing through the deodorizer to the outside; It may further include.

In the multi-stage waste drying apparatus according to the present invention, a plurality of drying chambers are arranged up and down in a drying furnace one by one, and the hot air is supplied to each drying chamber while transferring the waste in a zigzag form from the uppermost drying chamber to the lowermost drying chamber in turn, thereby allowing waste within a limited space. It is possible to lengthen the conveying path of and to lengthen the time for exposing the conveyed waste to hot air. Therefore, the drying efficiency of the waste can be improved.

In addition, it is possible to reduce the energy required to supply hot air by recovering the heated air of the drying chamber and reheating it.

In addition, by varying the temperature of the hot air supplied to each drying chamber to reduce the risk of ignition of waste, it is possible to efficiently use the energy according to the hot air supply.

Figure 1 shows a part of the configuration of the multi-stage waste drying apparatus according to the first embodiment of the present invention.
2 is a plan view showing a multi-stage waste drying apparatus according to a first embodiment of the present invention.
Figure 3 shows a part of the internal configuration of the drying of the multi-stage waste drying apparatus according to the first embodiment of the present invention.
Figure 4 shows the main configuration of the hot air supply apparatus of the multi-stage waste drying apparatus according to the first embodiment of the present invention.
Figure 5 shows a multi-stage waste drying apparatus according to a second embodiment of the present invention.
6 shows the main configuration of the first hot air supply device of the multi-stage waste drying apparatus according to the second embodiment of the present invention.
Figure 7 shows a multi-stage waste drying apparatus according to a third embodiment of the present invention.
Figure 8 shows the exhaust air handler of the multi-stage waste drying apparatus according to the third embodiment of the present invention.
9 shows a multi-stage waste drying apparatus according to a fourth embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a multi-stage waste drying apparatus according to the present invention will be described in detail.

In describing the present invention, the sizes and shapes of the components shown in the drawings may be exaggerated or simplified for clarity and convenience of explanation. In addition, terms that are specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. These terms are to be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the contents throughout the present specification.

Figure 1 shows a part of the configuration of a multi-stage waste drying apparatus according to a first embodiment of the present invention, Figure 2 is a plan view showing a multi-stage waste drying apparatus according to a first embodiment of the present invention, Figure 3 is a A part of the internal structure of the drying furnace of the multi-stage waste drying apparatus according to the first embodiment is shown, and FIG. 4 shows the main configuration of the hot air supply apparatus of the multi-stage waste drying apparatus according to the first embodiment of the present invention.

As shown in Figures 1 to 4, the multi-stage waste drying apparatus 10 according to the first embodiment of the present invention is for drying wastes containing moisture, such as organic waste or flammable waste using hot air, waste A drying furnace 11 having the plurality of drying chambers 12 introduced therein; a waste conveying device 24 installed in each of the plurality of drying chambers 12 for transferring waste; and a plurality of drying chambers 12 for introducing hot air. And a plurality of hot wind supply ducts 32 provided in each of the plurality of hot wind supply ducts 32 and a plurality of hot wind supply devices 36 for supplying hot air to each of the plurality of hot wind supply ducts 32. The multi-stage waste drying apparatus 10 according to the present invention has a structure in which hot air is applied to the waste while sequentially transferring the waste along the plurality of drying chambers 12 disposed up and down in the drying furnace 11, thereby transferring the waste path. Long and long time the waste is exposed to hot air, the drying efficiency of the waste is excellent.

As shown in FIG. 1 and FIG. 2, the drying furnace 11 has an inner space capable of accommodating waste therein, and the inner space of the drying furnace 11 is spaced vertically apart from the inside of the drying furnace 11. It is partitioned into the some drying chamber 12 by the some partition wall 13 provided. The plurality of partition walls 13 are coupled to the side walls 14 of the drying furnace 11. The top wall 15 of the drying furnace 11 is provided with a waste inlet 16 to which the waste inlet device 20 is connected, and this waste inlet 16 is a drying chamber (located at the top of the plurality of drying chambers 12). 12). And the lower wall 17 of the drying furnace 11 is provided with a waste outlet 18 to which the waste discharge device 22 is connected. The waste outlet 18 is connected to a drying chamber 12 located at the bottom of the plurality of drying chambers 12.

In the drying furnace 11, a plurality of drying chamber discharge paths 19 connected to the respective drying chambers 12 are provided. The plurality of drying chamber discharge paths 19 may be provided between the side walls 14 of the drying furnace 11 and the ends of each of the plurality of partition walls 13 as shown, or formed in each partition wall 13. May be Each drying chamber discharge passage 19 serves as a passage for moving the waste introduced into the corresponding drying chamber 12 downward. That is, the waste transported along the drying chamber 12 disposed in the upper portion is moved to the drying chamber 12 disposed in the lower portion through the drying chamber discharge passage 19 connected thereto, and the drying chamber 12 disposed in the lowermost portion is moved. The waste transported along can be moved to the waste outlet 18 below it via the drying chamber discharge passage 19 connected thereto.

As shown in FIG. 1, the drying chamber discharge path 19 is provided at the end of the drying chamber 12, and the drying chamber discharge paths 19 connected to each of the two drying chambers 12 adjacent to each other up and down are disposed opposite to each other. That is, the drying chamber discharge path 19 disposed above the two drying chamber discharge paths 19 disposed up and down adjacent to each other is disposed on one side wall 14 side of the drying furnace 11 and disposed below the drying chamber discharge path ( 19 is arranged on the side wall 14 opposite the drying furnace 11. Each partition wall 13 is arranged obliquely downward toward the drying chamber discharge path 19 connected to the drying chamber 12 partitioned thereby, so that the drying chamber 12 is inclined downward toward the drying chamber discharge path 19 connected thereto. do. When the drying chamber 12 is inclined downward toward the drying chamber discharge path 19, the waste transport device 24 may smoothly transfer the waste introduced into the drying chamber 12 to the drying chamber discharge path 19.

As shown in FIG. 1 and FIG. 2, the waste conveying apparatus 24 is for conveying the waste introduced into the drying chamber 12 toward the drying chamber discharge path 19, and may push the waste shaft 25 and the waste. A screw blade 26 disposed between the front end and the middle of the rotating shaft 25 so as to be disposed, and a plurality of grinding paddles 27 spaced between the middle and the rear end of the rotating shaft 25 to crush waste. Here, the tip of the rotary shaft 25 refers to the end disposed on the inlet side in which the waste flows, and the rear end of the rotary shaft 25 refers to the end of the drying chamber discharge path 19 through which the waste is discharged. The waste transfer device 24 is installed in a plurality of spaced apart at regular intervals for each drying chamber 12, and transfers the waste introduced into the drying chamber 12 toward the drying chamber discharge path 19 while stirring. In addition, the plurality of grinding paddles 27 provided in the waste transporting device 24 further increases the drying efficiency of the waste by crushing the transported waste.

A pulley 28 is coupled to the front end of the rotating shaft 25 of the waste transport device 24, and a drive belt 29 connected to the drive device 30 is connected to the pulley 28. The driving force of the drive device 30 is transmitted to the pulley 28 coupled to the rotating shaft 25 through the drive belt 29. In the drawing, a plurality of waste conveying devices 24 disposed in one drying chamber 12 are all rotated by receiving driving force from one driving device 30 through one driving belt 29, but the wastes are all rotated. The power transmission structure for the transfer device 24 can be changed to various other structures in addition to those shown. For example, the drive device 30 may be installed one-to-one on the waste transport device 24. In addition, the structure of the waste transport device 24 is not limited to the illustrated, and may be changed to various other structures capable of transferring the waste introduced into the drying chamber 12 toward the drying chamber discharge path 19.

Waste conveying devices 24 disposed in two drying chambers 12 adjacent to each other up and down are installed in each of the drying chambers 12 such that the waste conveying directions in the two drying chambers 12 are opposite to each other. 1, the waste is transferred from the right side to the left side in the upper side drying chamber 12 and flows into the lower side drying chamber 12 through the drying chamber discharge path 19, and to the left side in the lower side drying chamber 12. Is transferred to. In this way, the waste flowing into the waste inlet 16 passes through the plurality of drying chambers 12 in a zigzag form from the top to the bottom of the drying furnace 11 in a zigzag fashion, and then through the waste outlet 18, the waste discharge device 22. Is transferred to).

As shown in Figures 1 to 3, each drying chamber 12 is provided with a plurality of hot air supply ducts 32 for the introduction of hot air. The hot air supply duct 32 is coupled to the partition wall 13 and is disposed along the conveying direction of the waste between the plurality of waste conveying devices 24. The hot wind supply duct 32 has a hot air supply path 33 for the flow of hot air, and a plurality of injection holes 34 connected to the hot air supply path 33 to inject the hot air spaced apart along the conveying direction of the waste. do. The plurality of injection holes 34 are provided in a double row to face the waste transfer devices 24 disposed on both sides of the hot air supply duct 32. Thus, the plurality of injection holes 34 are disposed along the conveying direction of the waste, so that hot air can be smoothly and evenly supplied to the waste conveyed by the waste conveying apparatus 24. Of course, the specific structure of the hot air supply duct 32, the number of installations per layout chamber 12, the arrangement structure, etc. may be variously changed.

A hot air supply pipe 39 connected to the hot air supply device 36 is connected to the hot air supply duct 32. The hot air supply device 36 is provided in the same number as the drying room 12 so as to be connected to the drying room 12 one-to-one, and the hot air supply pipe 39 connected to each hot air supply device 36 is branched into one drying room ( All are connected with the some hot air supply duct 32 provided in 12). Although the plurality of hot air supply devices 36 are all made of the same structure, the temperature of the hot air supplied from each hot air supply device 36 may be controlled differently.

In other words, relatively high temperature hot air is supplied to the upper side drying chamber 12 which is relatively moist, and relatively low temperature hot air is supplied to the lower side drying chamber 12 having relatively low moisture. Do. Supplying hot air with high temperature to the lower drying chamber 12 through which the waste with relatively little moisture flows through the drying chamber 12 in turn may cause a problem of ignition of the waste, which is connected to the lower drying chamber 12. The hot wind supply device 36 is efficient to supply relatively low temperature hot wind by inputting little energy.

As shown in FIGS. 1 to 4, the hot air supply device 36 includes a hot air recovery pipe 37 connected to the drying chamber 12 so as to suck air from the drying chamber 12, and a hot air recovery pipe ( A hot air generator 38 for reheating and supplying hot air recovered through the air 37 and a hot air generator 38 and a corresponding drying chamber to guide the hot air blown from the hot air generator 38 to the drying chamber 12. 12 and one or more hot air supply pipes (39) connecting the plurality of hot air supply ducts (32). The hot air generator 38 is configured to heat the air passed through the centrifuge 40 and the centrifuge 40 connected to the hot air recovery pipe 37 to centrifuge the air sucked into the hot air recovery pipe 37. And a blower 42 for blowing air heated by the hot wind heater 41. These centrifugal separators 40, hot air heaters 41, blowers 42 and the like can be used in a variety of known structures.

In addition, the hot air generator 38 is a filter 43 for filtering foreign matter in the air passing through the centrifugal separator 40 and a dehumidifier for removing moisture contained in the air recovered through the hot air recovery pipe 37. (44), and an outside air heater 45 for heating and supplying outside air. The filter 43 may be one of various known structures, such as a wire mesh structure, and various kinds of well-known dehumidifiers 44 may be used. The outside air heater 45 serves to supply the outside air heated by burning fuel to the hot air supply pipe 39. When the fuel is combusted, oxygen in the air is consumed, and the heated air generated in this process has a low oxygen concentration. Thus, when the heated air having such a low oxygen concentration is supplied to the drying chamber 12 through the hot air supply pipe 39, the drying chamber ( 12) Lowering the oxygen concentration in the waste can further reduce the risk of waste ignition. The external air heater 45 may use various kinds of fuels capable of burning various kinds of fuels such as gaseous fuel, liquid fuel or solid fuel.

In the present invention, the specific structure of the hot air supply device 36 is not limited to that shown. That is, the hot air supply device 36 has the hot air recovery pipe 37, the hot air heater 41, the blower 42, and the hot air supply pipe 39 as basic components, and various additional components can be added or subtracted thereto. Can be. In addition, the specific structure of the drying furnace 11, the number and arrangement of the drying chamber 12 provided in the drying furnace 11, the number and arrangement of the waste transport device 24 installed in the drying furnace 11 is not limited to the illustrated and various Can be changed.

As described above, the multi-stage waste drying apparatus 10 according to the present invention arranges the plurality of drying chambers 12 in the drying furnace 11 in the up and down direction, and sequentially wastes the waste from the uppermost drying chamber 12 to the lowermost drying chamber 12. Since the hot air is supplied to each drying chamber 12 while being transferred in the form, it is possible to lengthen the conveying path of the waste within the limited space and to lengthen the time for exposing the conveyed waste to the hot air. Therefore, the drying efficiency of the waste can be improved. In addition, the energy required for hot air supply can be reduced by recovering the heated air of the drying chamber 12 and reheating it. In addition, by varying the temperature of the hot air supplied to each drying chamber 12, it is possible to reduce the risk of ignition of the waste, efficient drying.

Figure 5 shows a multi-stage waste drying apparatus according to a second embodiment of the present invention, Figure 6 shows a main configuration of the first hot air supply apparatus of the multi-stage waste drying apparatus according to a second embodiment of the present invention.

In the multi-stage waste drying apparatus 50 according to the second embodiment of the present invention shown in FIG. 5, waste is introduced into a drying furnace 11 and a drying furnace 11 having a plurality of drying chambers 12 into which waste is introduced. A waste input device 20 for discharging, a waste discharge device 22 for discharging the waste dried in the drying furnace 11, and a plurality of first hot air supply devices for supplying hot air to the plurality of drying chambers 12. And a second hot air supply device 57. Here, the drying furnace 11 is the same as the above-mentioned, and the waste conveying apparatus 24 and the hot air supply duct 32 (refer FIG. 1) provided in the drying furnace 11 are also the same as the above-mentioned.

The multi-stage waste drying apparatus 50 according to the second embodiment of the present invention supplies hot air to the plurality of drying chambers 12 provided in the drying furnace 11 by two hot air supply devices 51 and 57. The first hot wind supply device 51 recovers hot air from the upper drying chambers 12 into which wastes with relatively high humidity flow, and reheats it to supply hot air to these drying chambers 12, and a second hot wind supply device. Reference numeral 57 recovers hot air from the lower drying chambers 12 into which waste with relatively low humidity flows, and reheats it to supply the hot air to these drying chambers 12.

The structure of the first hot air supply device 51 and the second hot air supply device 57 may be the same, except that the first hot air supply device 51 supplies relatively high temperature hot air to the upper drying chambers 12. In addition, the second hot air supply device 57 is different in that it supplies relatively low temperature hot air to the lower drying chambers 12.

As shown in FIGS. 5 and 6, the first hot air supply device 51 is connected to these drying chambers 12 so as to suck in air from the drying chambers 12 arranged on the upper side of the drying furnace 11. Each of the plurality of hot air recovery pipes 52, the hot air generators 53 for reheating and supplying the hot air recovered through the hot air recovery pipes 52, the hot air generators 53, and the drying chambers 12, respectively. And a plurality of hot air supply pipes 54 for connecting the plurality of hot air supply ducts 32 installed therein. The hot air generator 53 has a centrifuge 40 connected to the hot air recovery pipe 52 for centrifuging the air sucked into the hot air recovery pipe 52, and a filter 43 for filtering foreign matter from the sucked air. ), A dehumidifier 44 for removing moisture in the sucked air, a hot air heater 41 for heating the sucked air, a blower 42 for blowing air heated in the hot air heater 41, and And an outside air heater 45 for heating and supplying outside air. The components of these first hot air supply devices 51 are as described above.

In addition, the first hot air supply device 51 further includes an outside air mixer 55 and a temperature sensor 56 connected to some hot air supply pipes 54 of the plurality of hot air supply pipes 54. The outdoor air mixer 55 serves to lower the temperature of the hot air supplied to the drying chamber 12 by mixing the outside air with the hot air supplied through the hot air supply pipe 54 connected to the drying chamber 12. The temperature of the hot wind blown by the hot wind generator 53 is set to the temperature of the hot wind supplied to the drying chamber 12 located in the uppermost part.

Therefore, the outside air mixer 55 or the temperature sensor 56 may not be installed in the hot air supply pipe 54 connected to the drying chamber 12 located at the top, and the hot air generator 53 is installed in the drying chamber 12 located at the top. Hot air blown from is supplied as it is. In addition, the remaining drying chamber 12 is supplied with hot air whose temperature is lowered by mixing the outside air with the hot air blown by the hot air generator 53 through the outside air mixer 55.

In addition to the drying chamber 12 located at the top, the temperature of the hot air supplied to each of the remaining drying chambers 12 is individually controlled by the amount of outside air mixing through the outside air mixer 55 installed in the hot air supply pipe 54 connected to the respective drying chambers 12. Can be controlled. For example, hot air can be supplied to the drying chambers 12 located on the upper side with a relatively small amount of outside air mixing, and hot air can be supplied to the drying chambers 12 located on the lower side in a relatively large amount. Since the temperature of the hot air decreases as the amount of outside air mixture increases, the temperature of the hot air supplied to each drying chamber 12 can be appropriately controlled by appropriately controlling the amount of outside air mixing. The amount of outside air mixed through the outside air mixer 55 may be adjusted through the detection temperature of the temperature sensor 56. That is, when the temperature sensor 56 detects the temperature of the hot air supplied through the hot air supply pipe 54, the outdoor air mixer 55 adjusts the amount of outdoor air mixed according to the detected temperature so that the hot air of a suitable temperature is applied to the drying chamber 12. Can be supplied.

The second hot air supply device 57 is different from the drying chamber 12 in which the hot air recovery pipe 52 and the hot air supply pipe 54 are connected, and its specific structure and operation are the same as those of the first hot air supply device 51 described above. . Since the second hot air supply device 57 supplies hot air to the drying chambers 12 into which waste having a relatively low moisture content flows, the second hot air supply device 57 produces hot air having a lower temperature than that of the first hot air supply device 51, thereby providing the corresponding drying chambers ( 12). Like the first hot air supply device 51, the temperature of the hot air supplied by the second hot air supply device 57 to each of the drying chambers 12 may be determined by using an air mixer 55 and a temperature sensor installed in the hot air supply pipe 54. 56). The temperature of the hot air blown by the hot wind generating device 53 of the second hot air supply device 57 is supplied to the drying chamber 12 positioned at the top of the plurality of drying chambers 12 to which the second hot air supply device 57 is connected. It is set to the temperature of hot air. Therefore, the hot air blown by the hot air generator 53 is supplied to the drying chamber 12 positioned at the top of the plurality of drying chambers 12 to which the second hot air supply device 57 is connected, and the outdoor air mixer is supplied to the remaining drying chambers 12. The outside air is mixed through the 55 to supply the hot air whose temperature is lowered. The outside air mixer 55 or the temperature sensor 56 may not be installed in the hot air supply pipe 54 connected to the drying chamber 12 positioned at the top of the plurality of drying chambers 12 to which the second hot air supply device 57 is connected. .

In the present invention, the number of installation of the hot air supply devices 51 and 57 for supplying hot air to the plurality of drying chambers 12 is not limited to two as shown, and may be variously changed. That is, the hot air supply apparatuses 51 and 57 are provided in a plurality less than the number of drying chambers 12, and each of the plurality of hot air supply apparatuses 51 and 57 is provided in two or more of the plurality of drying chambers 12. It may be connected to two or more drying chambers 12 so as to supply the. The specific structure of each hot air supply device 51 and 57 is not limited to the illustrated but may be variously changed.

On the other hand, Figure 7 shows a multi-stage waste drying apparatus according to a third embodiment of the present invention, Figure 8 shows a discharge air processor of the multi-stage waste drying apparatus according to a third embodiment of the present invention.

In the multi-stage waste drying apparatus 60 according to the third embodiment of the present invention illustrated in FIG. 7, waste is introduced into a drying furnace 11 and a drying furnace 11 having a plurality of drying chambers 12 into which waste is introduced. Waste injector 20 for discharging, a waste discharging device 22 for discharging the waste dried in the drying furnace 11, and a plurality of hot air supply devices 61 for supplying hot air to the plurality of drying chambers 12. ) And an exhaust air processor 63 for purifying air from the plurality of drying chambers 12 disposed above the plurality of drying chambers 12 and discharging the air into the outside air. Here, the drying furnace 11 is the same as the above-mentioned, and the waste conveying apparatus 24 and hot-air supply duct 32 (refer FIG. 1) provided in the drying furnace 11 are also the same as the above-mentioned.

The multi-stage waste drying apparatus 60 according to the third embodiment of the present invention recovers hot air from the drying chambers 12 in which wastes having a relatively low moisture content are transferred to the lower side among the plurality of drying chambers 12. The hot air is supplied to the plurality of drying chambers 12 by one hot air supply device 61 which is reheated. In addition, the water-containing air of the plurality of upper drying chambers 12 disposed relatively close to the waste inlet 16 is recovered through the exhaust air processor 63 without being reused and discharged to the outside air.

The hot air supply device 61 includes a plurality of hot air recovery pipes 52 and hot air recovery pipes 52 that are disposed at the lower side of the drying furnace 11 and are connected to the drying chambers 12 to which wastes containing less moisture are transferred. A plurality of hot air supply pipes connecting the hot air generator 53 for reheating and supplying the hot air recovered through the hot air generator; and a plurality of hot air supply ducts 32 installed in each of the hot air generator 53 and the plurality of drying chambers 12 ( 54 and a plurality of outside air mixers 55 and a plurality of temperature sensors 56 connected to some hot air supply pipes 54 of the plurality of hot air supply pipes 54. The hot air generator 53 is the same as the hot air generator 53 shown in FIG. 6.

The operation of the hot air supply device 61 is the same as the hot air supply device (51) (57) provided in the multi-stage waste drying apparatus 50 according to the second embodiment. The temperature of the hot air blown by the hot wind generator 61 is set to the temperature of the hot air supplied to the drying chamber 12 located at the top connected with the waste inlet 16. Therefore, the hot air blown by the hot air generator 53 is supplied to the drying chamber 12 located at the top thereof, and the remaining air is mixed with the outside air through the outdoor air mixer 55 to supply the hot air whose temperature is controlled. do. The outside air mixer 55 or the temperature sensor 56 may not be installed in the hot air supply pipe 54 connected to the drying chamber 12 positioned at the top.

A plurality of air suction pipes 64 and air suction pipes 64 are disposed on a relatively upper side of the plurality of drying chambers 12 and connected to the drying chambers 12 through which wastes having a high moisture content are transferred. A centrifuge (65) connected to the air suction pipe (64) for centrifuging the air sucked into the air, a filter (66) for filtering foreign matter in the air sucked into the air suction pipe (64), and an air suction pipe (64). And a deodorizer 67 for burning and deodorizing the air sucked into the air, and an exhaust pipe 68 connected to the deodorizer 67 to exhaust the air passing through the deodorizer 67 to the outside. Of course, the specific structure of the exhaust air handler 63 is not limited to that shown, and may be changed to various other structures capable of purifying or deodorizing air discharged from the drying chamber 12 and then discharging it to the outside air.

The multi-stage waste drying apparatus 60 according to the third embodiment of the present invention sucks only the air of the drying chambers 12 having a relatively low humidity among the plurality of drying chambers 12 and reheats them to the plurality of drying chambers 12. Supply. Therefore, even if hot air supplied into the drying furnace 11 is recovered and recycled, hot air of low humidity can be supplied to the drying chamber 12.

On the other hand, Figure 9 shows a multi-stage waste drying apparatus according to a fourth embodiment of the present invention.

The multi-stage waste drying apparatus 70 according to the fourth embodiment of the present invention shown in FIG. 9 includes a drying furnace 11 having a plurality of drying chambers 12 into which waste is introduced, and wastes into the drying furnace 11. Waste injecting device 20 for injecting, a waste discharging device 22 for discharging the dried waste in the drying furnace 11, and a hot air supply device 71 for supplying hot air to the plurality of drying chambers 12. And an exhaust air processor 72 for purifying the air in the plurality of drying chambers 12 disposed on the lower side of the plurality of drying chambers 12 and discharging the air to the outside air. Here, the drying furnace 11 is the same as the above-mentioned, and the waste conveying apparatus 24 and hot-air supply duct 32 (refer FIG. 1) provided in the drying furnace 11 are also the same as the above-mentioned.

The multi-stage waste drying apparatus 70 according to the fourth embodiment of the present invention is disposed on a relatively upper side of the plurality of drying chambers 12 and recovers hot air from the drying chambers 12 to which hot air is supplied at a relatively high temperature. The hot air is supplied to the plurality of drying chambers 12 by one hot air supply device 71. In addition, the air in the drying chambers 12 to which the relatively low temperature hot air is supplied is recovered and discharged to the outside after being treated through the exhaust air processor 72 without being reused.

The hot air supply device 71 is different from only the drying chambers 12 to which the hot air supply device 61 and the hot air recovery pipe 52 connected to the multi-stage waste drying apparatus 60 according to the third embodiment of the present invention are different from each other. There is only the specific configuration and the operation is the same. Exhaust air processor 72 is the same as the exhaust air processor 63 provided in the multi-stage waste drying apparatus 60 according to the third embodiment of the present invention, the drying chambers disposed on the relatively lower side of the drying furnace 11 The air in (12) is treated and discharged to the outside.

The multi-stage waste drying apparatus 70 according to the fourth embodiment of the present invention sucks and reheats the hot air of the drying chambers 12 to which hot air with a relatively high temperature is supplied among the plurality of drying chambers 12, and then the plurality of drying chambers. The hot air of the drying chambers 12 supplied to (12) and supplied with relatively low temperature hot air are discharged into the outside air after treatment such as purification or deodorization. Therefore, it is possible to reduce the energy for reheating the hot air recovered in the drying furnace (11).

In the multi-stage waste drying apparatus of the present invention, the installation number of the hot air supply device connected to the drying furnace, the connection structure with the drying chamber and the hot air supply structure, the installation number of the exhaust air processor or the connection structure with the drying chamber, and the air flow structure with the drying chamber May be variously modified in addition to those described above.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art can improve and modify the technical idea of the present invention in various forms. Accordingly, these modifications and variations are intended to fall within the scope of the present invention as long as it is obvious to those skilled in the art.

10, 50, 60, 70: multi-stage waste drying apparatus 11: drying furnace
12 dry chamber 13 partition wall
16: waste inlet 18: waste outlet
20: waste input device 22: waste discharge device
24: waste conveying device 25: rotating shaft
26: screw blade 27: grinding paddle
30: drive device 32: hot air supply duct
36, 51, 57, 61, 71: hot air supply device 37, 52: hot air recovery pipe
38, 53: hot air generator 39, 54: hot air supply pipe
40, 65: centrifuge 41: hot air heater
42: blower 43, 66: filter
44: dehumidifier 45: air heater
55: air mixer 56: temperature sensor
63: exhaust air handler 64: air intake pipe
68: exhaust pipe

Claims (12)

An inner space capable of accommodating waste, a plurality of partition walls spaced up and down in the inner space and partitioning the inner space into a plurality of drying chambers, and a drying chamber located at the top of the plurality of drying chambers for injecting wastes; A drying furnace having a waste inlet connected to the waste outlet and a waste outlet connected to a drying chamber located at the bottom of the plurality of drying chambers for discharge of the dried waste;
A plurality of drying chamber discharge passages provided to be connected to each of the plurality of drying chambers such that waste introduced into each of the plurality of drying chambers is discharged from each of the plurality of drying chambers and moved downward;
A plurality of waste transfer devices installed in each of the plurality of drying chambers to transfer waste introduced into each of the plurality of drying chambers toward a drying chamber discharge path connected to each of the plurality of drying chambers;
It is installed in the plurality of partition walls to introduce hot air into each of the plurality of drying chambers are disposed in each of the plurality of drying chambers along a conveying direction of waste, and a plurality of injection holes for spraying hot air are spaced along the conveying direction of waste. A plurality of hot air supply ducts formed; And
And at least one hot air supply device for supplying hot air to the plurality of hot air supply ducts.
The plurality of waste conveying apparatuses are installed in each of the plurality of drying chambers such that the conveying direction of the wastes is opposite to each other in two drying chambers adjacent to each other among the plurality of drying chambers, and the plurality of drying chamber discharge paths are installed in the drying chambers to which they are respectively connected. By being placed at the rear end of the waste conveying apparatus,
Waste introduced into the waste inlet passes through the plurality of drying chambers in a zigzag form and is discharged to the waste outlet.
A plurality of waste conveying apparatuses are installed per one drying chamber, and the hot air supply duct is disposed between the plurality of waste conveying apparatuses installed in one drying chamber, and the waste conveying apparatuses having spray nozzles provided thereon are disposed on both sides thereof. Multi-stage waste drying apparatus characterized in that it is provided in a double row to face.
delete The method according to claim 1,
Each of the plurality of waste conveying apparatuses may include a screw blade disposed between the rotary shaft and the front end of the rotary shaft so as to push the waste out, and a plurality of the waste shafts spaced between the rear end and the middle of the rotary shaft to crush waste. Multi-stage waste drying apparatus comprising a grinding paddle.
The method according to claim 1,
The plurality of partition walls are multi-stage waste drying apparatus, characterized in that arranged inclined downward toward the drying chamber discharge path connected to the drying chamber.
The method according to claim 1,
The hot air supply device,
At least one hot air recovery pipe connected to the inside of the drying furnace to suck the air therein;
A centrifugal separator connected to the hot air recovery pipe for centrifuging the air sucked into the hot air recovery pipe;
A hot air heater for heating the air passed through the centrifuge,
A blower for blowing air heated by the hot air heater;
And one or more hot air supply pipes connecting the blower and the plurality of hot air supply ducts.
6. The method of claim 5,
The hot air supply device is a multi-stage waste drying apparatus further comprises an air heater for supplying the outside air heated by burning the fuel to the hot air supply pipe.
The method according to claim 1,
At least one air suction pipe connected to the inside of the drying furnace to suck the air in the drying furnace, a centrifugal separator connected to the air suction pipe to centrifuge the air sucked into the air suction pipe, and the centrifuge And a discharge air processor including a deodorizer for burning and deodorizing the air passed through, and an exhaust pipe connected to the deodorizer for exhausting the air passing through the deodorizer to the outside.
The method according to claim 1,
The hot air supply device is provided with a plurality so as to be connected to the plurality of drying chambers one-to-one,
Each hot air supply device,
A hot air recovery pipe connected to the drying chamber to suck air from the drying chamber,
A centrifugal separator connected to the hot air recovery pipe for centrifuging the air sucked into the hot air recovery pipe;
A hot air heater for heating the air passed through the centrifuge,
A blower for blowing air heated by the hot air heater;
And a hot air supply pipe connecting the blower and the hot air supply duct installed in the drying chamber.
The method according to claim 1,
The hot air supply device is provided with a plurality less than the plurality of drying chamber, each of the plurality of hot air supply device supplies hot air to at least two of the plurality of drying chamber,
Each hot air supply device,
A plurality of hot air recovery pipes connected to the drying chambers to suck air from the drying chambers;
A centrifugal separator connected to the plurality of hot air recovery tubes for centrifuging the air sucked into the plurality of hot air recovery tubes;
A hot air heater for heating the air passed through the centrifuge,
A blower for blowing air heated by the hot air heater;
And a plurality of hot air supply pipes connecting the blowers and the hot air supply ducts installed in the drying chambers.
The method of claim 9,
Each hot air supply device,
And one or more external air mixers connected to one or more of the hot air supply pipes for mixing the outside air with the hot air supplied to the hot air supply ducts through the hot air supply pipes connected to the drying chambers. Device.
The method according to claim 1,
The hot air supply device,
A plurality of hot air recovery pipes connected to some drying chambers among the plurality of drying chambers,
A centrifugal separator connected to the plurality of hot air recovery tubes for centrifuging the air sucked into the plurality of hot air recovery tubes;
A hot air heater for heating the air passed through the centrifuge,
A blower for blowing air heated by the hot air heater;
And a plurality of hot air supply pipes connecting the blower and the hot air supply ducts installed in the plurality of drying chambers.
The method of claim 11,
One or more air intake pipes connected to a drying room to which the hot air recovery pipes of the hot air supply device are not connected, and a centrifugal connection to the one or more air intake pipes for centrifuging the air sucked into the one or more air intake pipes. And an exhaust air processor having a separator, a deodorizer for burning and deodorizing the air passing through the centrifuge, and an exhaust pipe connected to the deodorizer for exhausting the air passing through the deodorizer to the outside. Multi-stage waste dryer.

Images