BR112020007434A2 - mechanical loader type incinerator to burn object to be incinerated - Google Patents

Abstract

A mechanical charger type incinerator is provided to burn objects to be incinerated and includes a drying stage (11), a combustion stage (12) and a post-combustion stage (13), each stage having a plurality of fixed fire grills (15) and a plurality of mobile fire grills (16), and in which the objects to be incinerated supplied from a feeder (4) are subjected to drying, combustion and post-combustion while sequentially transporting the objects to be incinerated through the drying stage (11), the combustion stage (12) and the post-combustion stage (13), in which the drying stage (11) is arranged to be tilted so that one side downstream in a transport direction is directed downstream, the combustion stage (12) is connected to the drying stage (11) and arranged to be tilted so that the end of the downstream side of it in the direction of transportation is directed upstream, and the powder stage s-combustion (13) is connected to the combustion stage (12) and arranged to be tilted so that the end of the downstream side of it in the direction of transport is directed upstream.

Description

"MECHANICAL CHARGER TYPE INCINERATOR TO BURN OBJECT TO BE INCINERATED" TECHNICAL FIELD

[001] The present invention relates to a mechanical charger type incinerator to burn an object to be incinerated such as waste.

[002] The priority is claimed in Japanese Patent Application No. 2017-201342, filed on October 17, 2017, the content of which is incorporated here by reference.

TECHNICAL FUNDAMENTALS

[003] A mechanical loader-type incinerator capable of efficiently incinerating a large quantity of objects to be incinerated without selection is known as an incinerator to incinerate objects to be incinerated as waste. The mechanical loader-type incinerator is equipped with a plurality of treatment stages including a drying stage to dry objects, a combustion stage to burn objects, and a post-combustion stage to further burn objects.

[004] In order to reliably incinerate the objects, an angle of inclination of the mechanical loader was studied. As described in Patent Document 1, for example, the angle of inclination of the mechanical loader can be tilted so that one side downstream in a transport direction of an installation surface of all stages of the drying stage, the drying stage. combustion, and the post-combustion stage is directed downwards. In the following description, for example, when the downstream side in the direction of transport of the installation surface of the drying stage is directed downwards, the drying stage is simply referred to as being directed downwards (the same also applies). applies to the combustion stage and the post-combustion stage).

[005] In addition, as described in Patent Document 2, there is a configuration in which the drying stage is tilted downwards, and the combustion stage and the post-combustion stage are laid out horizontally, as described in Document of Patent 3, there is a configuration in which the drying stage and the combustion stage are tilted downward and the downstream side in the direction of transport of the post-combustion stage installation surface is tilted to above, and as described in Patent Document 4, there is a configuration in which all stages are tilted upwards. For example, when the end of the downstream side in the direction of transport of the installation surface of the combustion stage is directed upwards, the combustion stage is simply referred to as being directed upwards (the same also applies to the the drying stage and the post-combustion stage).

CITATION LIST PATENT DOCUMENTS

[006] Patent Document 1: Unexamined Japanese Patent Application, First Publication No. H06-265125

[007] Patent Document 2: Unexamined Japanese Utility Publication Model No. H06-84140

[008] Patent Document 3: Examined Japanese Patent Publication No. S57-12053

[009] Patent Document 4: Unexamined Japanese Patent Application, First Publication No. S50-65062

SUMMARY OF THE INVENTION TECHNICAL PROBLEM

[010] Incidentally, objects to be incinerated with various properties (materials, shapes, moisture content) can be loaded into a mechanical charger type incinerator, but objects to be incinerated formed from a slippery material or having a format to be easy to roll over yourself

as a spherical shape, or objects to be incinerated with a high moisture content (including large amounts of water) it can be difficult to incinerate in the same mechanical charger type incinerator as that used for other objects to be incinerated.

[011] That is, in mechanical loader type incinerators described in Patent Documents 1, 2, and 3, since the drying stage is tilted down and the combustion stage is tilted down or disposed horizontally, objects to incinerated in a way that easily rolls can be transported to the post-combustion stage earlier than other materials, so it can be a problem that the object to be incinerated is discharged while it is still burning without having been burned. sufficiently incinerated.

[012] In addition, in the mechanical loader-type incinerator described in Patent Document 4, since all of the drying stage, the combustion stage, and the post-combustion stage are tilted upward, objects to be incinerated in which slippery materials are included or have a shape to be easy to roll on itself or objects to be incinerated with a high moisture content are gathered at the bottom of a stage (a descending wall) arranged between the feeder and the drying stage, and since the object to be incinerated is difficult to be transported to the combustion stage, in some cases, there is a problem that it is necessary to limit a quantity of loading or temporarily stop loading.

[013] An object of the present invention is to provide a mechanical charger type incinerator to burn objects to be incinerated as waste capable of continuously loading the objects regardless of its properties and eliminating combustion residues from the objects.

SOLUTION TO THE PROBLEM

[014] According to a first aspect of the present invention, a mechanical charger type incinerator is provided to burn objects to be incinerated as waste that feeds the incinerated object from a feeder and performs each of the drying, combustion, and post-combustion, while sequentially transporting objects, in a drying stage, a combustion stage, and a post-combustion stage, which include a plurality of fixed fire grills and a plurality of mobile fire grills, where the drying stage is arranged to be tilted so that a downstream side in a transport direction is directed downwards, the combustion stage is connected to the drying stage and arranged to be tilted so that the end of the downstream side of it in the direction of transport is directed upwards, and the post-combustion stage is connected to the combustion stage and arranged to be tilted so that the end of the side downstream of it in the direction of transport is directed upwards.

[015] According to such a configuration, since the drying stage is tilted downwards in the direction of transport, it is possible to transport the objects to be incinerated with any properties to the combustion stage without delay. In addition, since the combustion stage and the post-combustion stage are tilted upwards, objects do not easily slide downwards or roll downwards after the combustion stage and are sufficiently burned and transported.

[016] That is, while incinerating objects in which slippery materials are included or shaped to be easy to roll over, as it is transported to the combustion stage at an early stage due to scrolling in the drying stage or similar, there is a probability that it may not be sufficiently dry at the drying stage. However, since the combustion stage and the post-combustion stage are tilted upwards, the objects to be incinerated roll downwards in the drying stage no longer roll downwards in the combustion stage and in the post-combustion stage, and the objects to be incinerated are sufficiently dry and incinerated in the combustion stage as necessary. Since the objects to be incinerated having a high water content are transported to the combustion stage while being dried without remaining in the drying stage, the objects to be incinerated are also sufficiently incinerated in the combustion stage.

[017] As a result, regardless of the properties of the object to be incinerated, it is possible to continuously load the object to be incinerated, and it is possible to eliminate residual burning of the object to be incinerated.

[018] In the mechanical loader-type incinerator, an end portion of the post-combustion stage on the downstream side in the direction of transport can be disposed in a substantially vertical direction in the same position as the end portion of the combustion stage on the downstream side in the direction of transport, or higher than the end portion of the combustion stage.

[019] According to such a configuration, even in the case where the objects to be incinerated roll down in the drying stage, it is possible to prevent the objects to be incinerated from being discharged from the stage. afterburning without being sufficiently burned.

[020] In the mechanical loader type incinerator, each of the fixed fire grills and the mobile fire grills can be arranged to be lowered so that the end of the downstream side of it in the direction of transport is directed upwards in relation to the installation surfaces of the drying stage, the combustion stage, and the post-combustion stage.

[021] With such a configuration, the mobile fire grills can be operated to agitate and feed the objects to be incinerated in the fire grills attached to the downstream side in the direction of transport while stirring.

[022] In the mechanical loader type incinerator, each of the drying stage, the combustion stage, and the post-combustion stage can have a drive mechanism configured to activate the plurality of included mobile fire grills, and speeds of activation in the drying stage, the combustion stage, and the post-combustion stage are set to the same or different speed in at least one of the drying stage, the combustion stage, and the post-combustion stage in relation to to the other.

[023] According to such a configuration, it is possible to change the transport speeds of each stage depending on the properties of the objects to be incinerated.

[024] In the mechanical charger type incinerator, the combustion stage and the post-combustion stage can be continuously connected to each other without steps.

[025] With such a configuration, it is easier to incinerate the object to be incinerated continuously.

[026] In the mechanical loader-type incinerator, at least one of the mobile fire grates in the drying stage may be a projecting fire grid in which a projection is formed at the distal end of the projecting fire grid.

[027] With such a configuration, it is possible to improve the agitation effect of the objects to be incinerated when the mobile fire grills are alternated.

[028] In the mechanical loader type incinerator, at least one of the mobile fire grills of the combustion stage may be a projecting fire grid in which a projection is formed at the distal end of the projecting fire grid.

[029] In the mechanical loader type incinerator, an angle of inclination of the mechanical loader of the drying stage can be arranged at an angle between -15º and -25º, and the angle of inclination of the mechanical loader of the combustion stage and the post-combustion can be arranged at an angle between + 5º and + 15º.

[030] Preferably, the angle of inclination of the mechanical loader of the drying stage can be -20º, and the angle of inclination of the mechanical loader of the combustion stage and the post-combustion stage can be arranged at + 10º.

[031] According to such a configuration, since the length of the necessary mechanical charger can be reduced, it is possible to supply a small and economical mechanical charger type incinerator.

ADVANTAGE EFFECTS OF THE INVENTION

[032] According to the present invention, it is possible to continuously load the objects to be incinerated, regardless of the properties of the objects to be incinerated, and it is possible to eliminate the combustion residues of the objects.

BRIEF DESCRIPTION OF THE DRAWINGS

[033] Figure 1 is a view showing a schematic configuration of a mechanical loader type incinerator according to a first embodiment of the present invention.

[034] Figure 2 is a view to explain an angle of inclination of the mechanical charger of a mechanical charger type incinerator according to the first embodiment of the present invention.

[035] Figure 3 is a side view illustrating a fire grille shape of the mechanical loader type incinerator according to the first mode of the present invention.

[036] Figure 4 is a graph that explains an adequate range of the angle of inclination of the mechanical loader of a drying stage is an angle between -15º and -25º.

[037] Figure 5 is a graph that explains an adequate range of the angle of inclination of the mechanical loader of a combustion stage is an angle between + 5º and + 15º.

[038] Figure 6 is a graph that explains why the appropriate range of the angle of inclination of the mechanical loader of the combustion stage is between + 8º and + 12º and an ideal value is + 10º in view of both the stage drying and combustion stage.

[039] Figure 7 is a view to explain an angle of inclination of the mechanical charger of a mechanical charger type incinerator according to a second embodiment of the present invention.

DESCRIPTION OF THE MODALITIES First modality

[040] Next, a mechanical charger type incinerator of the present invention will be described in detail with reference to the drawings. The mechanical loader type incinerator of the present modality is a mechanical loader type incinerator for combustion of objects to be incinerated as waste, and, as illustrated in Figure 1, includes a funnel 2 to temporarily store the T objects to be incinerated, an incineration furnace 3 to burn T objects, a feeder 4 to feed T objects to incineration furnace 3, a mechanical loader 5 (including fire grills 15 and 16 from a drying stage 11, a combustion 12, and a post-combustion stage 13) provided on the underside of the incineration furnace 3, and an air box 6 provided below the mechanical charger 5.

[041] The feeder 4 pushes the T objects continuously fed on a feed table 7 in the incineration furnace 3 through the funnel 2. The feed

switch 4 is alternated on the feed table 7 with a predetermined stroke by a feeder drive device 8.

[042] The air box 6 supplies primary air from a fan (not shown) to each part of the mechanical charger 5.

[043] The incineration furnace 3 is provided above the mechanical charger 5 and has a combustion chamber 9 including a primary combustion chamber and a secondary combustion chamber. A fan 10 for supplying secondary air to the combustion chamber 9 is connected to the incineration furnace 3.

[044] The mechanical loader 5 is a combustion device in which the fire grills 15 and 16 are arranged in a gradual manner. T objects are burned in the mechanical magazine 5.

[045] Next, a direction in which T objects are transported is referred to as a transport direction D. T objects are transported in mechanical loader 5 in transport direction D. In Figures 1, 2 and 3, a right side it is a downstream side D1 in the transport direction. In addition, a surface on which fire grilles 15 and 16 are attached is referred to as an installation surface, and an angle in the transport direction D formed by a horizontal surface and the installation surface centered at the ends to The amount (11b, 12b and 13b) of the drying stage, the combustion stage or the post-combustion stage is referred to as the angle of inclination of the mechanical loader (an installation angle). When the end of the downstream side of the installation surface in the transport direction is directed upwards from the horizontal plane, the angle of inclination of the mechanical loader is set to a positive value, and when the downstream side of the installation surface in the transport direction is directed downwards from the horizontal plane, the inclination angle of the mechanical loader is set to a negative value.

[046] The mechanical loader 5 has, in order from the upstream side in the direction of transport of the T objects, a drying stage 11 to dry the T objects, a combustion stage 12 to burn the T objects, and a stage afterburning 13 to completely burn unburnt components (afterburning). In the mechanical loader 5, drying, combustion, and post-combustion are performed, while sequentially transporting the T objects in the drying stage 11, in the combustion stage 12, and in the post-combustion stage 13.

[047] Each of stages 11, 12 and 13 has a plurality of fixed fire grills 15 and a plurality of mobile fire grills 16.

[048] The fixed fire grills 15 and the mobile fire grills 16 are alternately arranged in the transport direction D. The mobile fire grids 16 are alternated in the transport direction D. The T objects in the mechanical loader 5 are transported and agitated by the alternating movement of the mobile fire grills 16. That is, the lower layer portions of the T objects are moved and replaced with upper layer portions.

[049] The drying stage 11 receives the T objects that are pushed out by the feeder 4 and fall into the incineration oven 3, evaporates the moisture in the objects to be incinerated and partially decomposes the T objects. The combustion stage 12 ignites the dried T objects in the drying stage 11 using the primary air fed from the air box 6 below the combustion stage 12 and burning the volatile matter and the fixed carbon content. The post-combustion stage 13 burns the unburned content as the fixed carbon content that has passed without being sufficiently burned in the combustion stage 12 until the unburned content is completely gray.

[050] An ash outlet 17 is provided at the post-combustion stage outlet 13. The ash is discharged from the incineration furnace 3 via the ash outlet 17.

[051] Each of the drying stage 11, the combustion stage 12, and the post-combustion stage 13 have a drive mechanism 18 to drive the mobile fire grills 16. That is, the drying stage 11, the combustion stage 12, and post-combustion stage 13 each have a separate drive mechanism 18 to drive the plurality of mobile fire grills 16.

[052] The drive mechanism 18 is attached to a beam 19 provided in the mechanical loader 5. The drive mechanism 18 has a hydraulic cylinder 20 attached to the beam 19, an arm 21 operated by the hydraulic cylinder 20, and a beam 22 connected to a distal end of the arm 21. The beam 22 and the movable fire grills 16 are connected to each other via a support 23.

[053] According to the drive mechanism 18 of this modality, the arm 21 is operated by the expansion and contraction of the rod of the hydraulic cylinder 20. With the movement of the arm 21, the beam 22 configured to move along each of the surfaces of installation 11a, 12a and 13a of the mechanical loader 5 moves, and the mobile fire grills 16 connected to the beam 22 are activated.

[054] Although hydraulic cylinder 20 can be used as the drive mechanism 18, there is no limitation to it, and for example, a hydraulic motor, an electric cylinder, a conductive linear motor, or the like can be adopted. In addition, the shape of the drive mechanism 18 is not limited to that of the mode described above, and any shape can be adopted as long as the mobile fire grills 16 can be made to alternate. For example, instead of discarding the arm 21, the beam 22 and the hydraulic cylinder 20 can be connected directly to each other and actuated.

[055] The mechanical loader type 1 incinerator of the present modality can define the activation speed of the mobile fire grills 16 in the drying stage 11, in the combustion stage 12, and in the post-combustion stage 13 for the same speed or for different speeds in at least one of the drying stage 11, the combustion stage 12, and the post-combustion stage 13 in relation to the other.

[056] For example, when the T objects that need to be sufficiently burned in the combustion stage 12 are loaded, the firing speeds of the mobile fire grills 16 of the combustion stage 12 are reduced, and the transport speed is decreased of T objects in combustion stage 12, T objects can be sufficiently burnt.

[057] As illustrated in Figures 2 and 3, the fixed fire grills 15 and the mobile fire grills 16 are arranged so that the end of the downstream side of the same in the direction of transport is directed upwards in relation to the surfaces of installation 11a, 12a and 13a of drying stage 11, combustion stage 12, and post-combustion stage 13. Furthermore, fire grills 15 and 16 are arranged so that the distal ends of the grating fire 15 and 16 are directed to the downstream side D1 in the direction of transport. Therefore, the mobile fire grills 16 are operated to send the objects T on the fixed fire grills 15 to the downstream side D1 in the direction of transport.

[058] Some of the mobile fire grills 16 of drying stage 11 can be projecting fire grills 16P, each of which has a protrusion (others are normal fire grids as will be described later). As shown in Figure 2, each of the mobile fire grills 16 in a specific area R1, which corresponds to 50% to 80% of the entire area of the drying stage 11 from the downstream side D2 to the upstream in the direction of transport D, is the protruding fire grille 16P. Since the drying stage is provided with protruding fire grids 16P, it is possible to improve the stirring power of the drying stage.

[059] As shown in Figure 3, the protruding fire grille 16P has a plate-like fire grille body 25 and a triangular protrusion 26 formed at the distal end of the fire grate body 25. The protrusion 26 projects upward to from the upper surface of the fire grille body 25. The shape of the projection 26 is not limited to this, and can be, for example, trapezoidal or welded.

[060] Here, each of the fixed fire grilles 15 in Figure 3 is a fire grate with no protrusion on the upper surface of its distal end, and this shape is called a normal fire grate.

[061] In the present modality, some of the mobile fire grills 16 are defined as the protruding fire grills 16P, but are not limited to these, and both the mobile fire grills 16 and the fixed fire grills 15 can be the grids protruding fire extinguishers.

[062] In addition, the area in which protruding 16P fire grills are provided is not limited to the area mentioned above, and for example, 16P protruding fire grids can be used for all fire grids in the fire stage. drying 11. Furthermore, depending on the properties or types of the T objects, all fire grids (fixed fire grate and mobile fire grate) in the drying stage can be the normal fire grids.

[063] As similar to drying stage 11, some of the mobile fire grills 16 of combustion stage 12 are projecting fire grids 16P. Specifically, each of the mobile fire grills 16 in a specific area R2, which corresponds to 50% to 80% of an entire area of the combustion stage 12 from the downstream side to the upstream side in the direction of transport , is the protruding fire grill 16P. The other mobile fire grills 16 of combustion stage 12 are the normal fire grills. As in the drying stage, both mobile fire grills 16 and fixed fire grills 15 can be protruding grids, depending on the properties and types of T objects, and all fire grids (fixed fire grids and fire grids). incen-

furniture) can be used like normal fire grills.

[064] In the fire grills of the post-combustion stage 13, both the mobile fire grills 16 and the fixed fire grills 15 are illustrated as the normal fire grids in Figure 2, but as in the drying stage 11 and the combustion stage 12, protruding fire grills can be adopted.

[065] Next, the angle of inclination of the mechanical loader (installation angle) of the drying stage 11, the combustion stage 12, and the post-combustion stage 13 will be described.

[066] As illustrated in Figure 2, the drying stage 11 of the mechanical loader 5 of the present embodiment is laid down. That is, an installation surface 11a of the drying stage 11 is inclined so that the downstream side in the transport direction is lower. Specifically, an angle of inclination of the mechanical loader 1 of the drying stage 11, which is the angle between the horizontal plane centered on the end portion 11b on the side upstream of the drying stage 11 and the transport direction side of the drying surface. installation 11a is -15º (minus 15 degrees) to -25º (minus 25 degrees).

[067] The combustion stage 12 of the mechanical loader 5 of the present mode is arranged upwards. That is, the installation surface 12a of the combustion stage 12 is inclined so that the downstream side in the transport direction is higher. More specifically, an angle of inclination of the mechanical loader 2 of the combustion stage 12, which is an angle between the horizontal plane centered in the upstream end portion 12b of the combustion stage 12 and the side of the surface transport direction of installation 12a is + 5º (plus 5 degrees) to + 15º (plus 15 degrees).

[068] The post-combustion stage 13 of the mechanical loader 5 of this mode is arranged upwards. That is, the installation surface 13a of the post-combustion stage 13 is tilted so that the downstream side in the transport direction becomes higher. More specifically, an angle of inclination of the mechanical loader 3 of the afterburn stage 13, which is an angle between the horizontal plane centered on the upstream end portion 13b of the afterburn stage 13 and the side of the transport direction of the installation surface 13a, it is + 5º (plus 5 degrees) to + 15º (plus 15 degrees).

[069] A step (a descending wall) 27 is formed between the drying stage 11 and the combustion stage 12. An end portion 11c of the drying stage 11 on the downstream side in the direction of transport is formed to be higher in the vertical direction than the end portion 12b of the combustion stage 12 on the upstream side in the transport direction.

[070] Likewise, a step (descending wall) 28 is formed between the combustion stage 12 and the post-combustion stage 13. An end portion 12c of the combustion stage 12 on the downstream side in the direction transport is formed to be higher in the vertical direction than an end portion 13b of the post-combustion stage 13 on the upstream side in the transport direction.

[071] The end portion 12c of the combustion stage 12 on the downstream side in the transport direction and the end portion 13c of the post-combustion stage 13 on the downstream side in the transport direction are in substantially the same position on the vertical direction or the end portion 13c of the post-combustion stage 13 is arranged above the end portion 12c of the combustion stage 12 in the vertical direction. The mechanical loader-type incinerator 1 of the present embodiment is an example in which the end portion 12c of the combustion stage 12 on the downstream side in the direction of transport and the end portion 13c of the post-combustion stage 13 on the side downstream in the direction of transport are located in the same position in the vertical direction.

[072] Next, the reason why the angle of inclination of the mechanical loader of drying stage 11 is set to an angle between -15º (minus 15 degrees) and -25º (minus 25 degrees) will be described.

[073] The function of drying stage 11 is to dry and efficiently remove moisture from T objects using the radiant heat from the flame above the T objects and the sensitive heat of the primary air from the bottom of the fire grills.

[074] Here, radiation heat from the flame has a higher contribution to drying than the sensitive heat from primary air, and drying of the upper layer portion of T objects proceeds easily.

[075] For this reason, the drying speed is improved by moving the lower layer portion of the T objects upwards by agitating the fire grilles and replacing the lower layer portion with the upper layer portion.

[076] However, even when the stirring operation is carried out, since there should essentially be no incineration in the drying stage 11, it is necessary to ensure a sufficient length so that the evaporation of the moisture proceeds sufficiently. As the length increases, the size of the incinerator increases, and the cost also increases. Therefore, it is necessary to make the length of the mechanical loader as short as possible.

[077] If an absolute value of the angle of inclination of the mechanical loader is greater than an angle of rest of the T objects, since the T objects collapse under their own weight and layers of the T objects are not formed, the load - mechanical generator 5 does not work properly. On the other hand, if the absolute value of the angle of inclination of the mechanical loader is less than the landing angle of the T objects, the mechanical loader 5 works properly, but the movement of the T objects due to gravity (movement due to its own weight) decreases. In addition, when the installation surface is directed upwards, that is, when the angle of inclination of the mechanical loader is inclined to a positive value (more value), gravity acts in a direction to push the T objects back from the direction of transport.

[078] When the transport quantity of T objects due to the mechanical loader 5 is less than the loaded quantity of T objects, the capacity of the mechanical loader 5 is reached up to the transport limit and the mechanical loader 5 does not can incinerate the loaded amount of the T object properly.

[079] The ideal angle of inclination of a mechanical loader differs depending on the number of T objects to be loaded and the moisture content of the T objects. Here, the description will be provided on the assumption that a case in which the quantity of the T objects to be loaded is high and the moisture content is high (the amount of moisture is large) is a case in which the load of the loaded objects is large. On the contrary, a case in which the number of T objects to be loaded is small and the moisture content is low is a case in which the load of the loaded objects is small.

[080] Figure 4 illustrates a graph in which a horizontal axis represents an angle of inclination of the mechanical loader of drying stage 11, a vertical axis represents a length of the necessary mechanical loader of drying stage 11, and in the order of a case (1) where the load of the loaded objects is the highest for a case (4) in which the load of the loaded objects is the lowest, a relationship between the angle of inclination of the mechanical loader of drying stage 11 and the length of the required mechanical loader from drying stage 11 is plotted.

[081] Here, the length of the mechanical loader required is the distance at which 95% of the humidity of the loaded objects T is dried. “Angle of rest” on the horizontal axis represents the angle of rest of T objects.

[082] As illustrated in the graph in Figure 4, an angle of inclination of the mechanical loader of -30º is the limit to form the layer of the T objects. In relation to the angle of inclination of the mechanical loader of the layer formation limit, the length of the required mechanical loader decreases as the angle of inclination of the mechanical loader is reduced. However, when the tilt angle of the mechanical loader returns to a positive value, the length of the required mechanical loader gradually becomes longer. This is because when the angle of inclination of the mechanical loader becomes a positive value, the installation surface is directed upwards and the transport speed becomes slower, and as a result, the layer of the T objects becomes thick and is difficult to dry the T objects in the bottom layer to proceed.

[083] It should be noted that, in the four cases of case (1) in which the load of T objects to be loaded is the largest until the case (4) in which the load of T objects to be loaded is the smallest, no matter what the properties or quantity of the T objects, the angle of inclination of the mechanical loader of the ideal drying stage 11 at which the T objects can be properly processed and the length of the mechanical loader can be defined as the smaller has an appropriate range of an angle between -15º (minus 15 degrees) and -25º (minus 25 degrees). In addition, the ideal value is -20º (minus 20 degrees).

[084] Next, in the case where the tilting angle of the mechanical drying stage 11 loader is set to be within the appropriate range as described above, the reason why it is appropriate to make the tilting angle of the mechanical drying stage 11 combustion 12 between + 5º (plus 5 degrees) and + 15º (plus 15 degrees) will be explained.

[085] The function of combustion stage 12 is to maintain the temperature of the layer of T objects by radiant heat from the flame and self-combustion heat, and to promote the generation of combustible gas by the thermal decomposition of volatile matter,

and promote the combustion of the fixed carbon that remains after thermal decomposition.

[086] Here, since the time required for combustion of the fixed carbon is longer than the time required for volatilization of the volatile combustible gas, the length of the necessary mechanical charger for combustion stage 12 is determined according to the time required for combustion of fixed carbon.

[087] Figure 5 illustrates a graph in which, in a case where the angle of inclination of the mechanical loader of drying stage 11 is defined in the appropriate range as described above, a horizontal axis represents the angle of inclination of the loader mechanical of the combustion stage, the vertical axis represents the length of the necessary mechanical loader of the combustion stage, and in the order from the case (1) in which the load of the loaded objects is the largest until the case (4) in which the load of the loaded objects is the smallest, a relationship between the angle of inclination of the mechanical loader of the combustion stage and the length of the necessary mechanical loader of the combustion stage is plotted. Here, the length of the required mechanical loader for the combustion stage is the distance at which 95% of the fuel content volatilizes or burns.

[088] As shown in Figure 5, the angle of inclination of the mechanical loader -30º is the limit of formation of the layer of T objects. For the angle of inclination of the mechanical loader of the limit of formation of the layer, the length of the required mechanical loader decreases as the angle becomes loose. Considering the transport limit, the appropriate range of the angle of inclination of the mechanical loader can be defined for the range surrounded by the single dashed-dotted line illustrated in Figure 5.

[089] Even when the load of the loaded objects is large in the drying stage 11, since, the drying stage 11 has the angle of inclination of the mechanical loader within the appropriate range, the reduction of the water content and the re-

reduction in the volume of the waste are accelerated. So, for example, even if the load corresponds to (1) in the drying stage 11, since the load changes to that corresponding to (3) and (4) in the combustion stage 12, the largest angle of inclination of the mechanical charger can be adopted in the combustion stage 12. That is, since the combustion stage can be directed upwards, it is possible to guarantee the required retention time for combustion of fixed carbon, and even more the length of the charger mechanical can be reduced.

[090] Figure 6 is a graph in which a horizontal axis represents the angle of inclination of the mechanical loader of the combustion stage 12, a vertical axis represents the length of the mechanical loader required for both the drying stage 11 and the drying stage. combustion 12, and in the order from case (1) in which the load of T objects to be loaded is the largest until case (4) in which the load of T objects to be loaded is the lowest, a relationship between the Inclination angle of the mechanical loader for combustion stage 12 and the length of the mechanical loader required for both drying stage 11 and combustion stage 12 is plotted. Here, the tilting angle of the mechanical loader for drying stage 11 is set to an ideal value of -20º (minus 20 degrees).

[091] As shown in Figure 6, when considering the transport limit, the appropriate angle range for the mechanical loader of combustion stage 12 is an angle between + 8º (plus 8 degrees) and + 12º ( plus 12 degrees). In addition, in the case where the angle of inclination of the mechanical loader of the drying stage 11 is the ideal value of -20º (minus 20 degrees), the ideal value of the inclination angle of the mechanical loader of the combustion stage 12 is + 10º (plus 10 degrees).

[092] Since the lengths of the mechanical loader required for the drying stage 11 and the combustion stage 12 can be as short as possible by adjusting the respective angle of inclination of the mechanical loader to the appropriate ranges, particularly ideal values even if post-combustion stage 13 is included, it is possible to provide a small and economical mechanical charger as compared to the conventional one.

[093] According to this modality, since the drying stage 11 is tilted downwards, it is possible to transport any type of T objects to the combustion stage 12 without delay. In addition, since combustion stage 12 and post-combustion stage 13 are tilted upwards, T objects do not easily slide downwards or roll downwards to the downstream side of combustion stage 12 and are sufficiently burned and transported.

[094] That is, while incinerating T objects in which slippery materials are included or shaped to be easy to roll over, since the objects are transported to combustion stage 12 earlier due to rolling in drying stage 11 or similar, there is a probability of not being able to dry completely in drying stage 11. However, since combustion stage 12 and post-combustion stage 13 are tilted upwards , T objects roll down in drying stage 11 no longer roll down in combustion stage 12 and post-combustion stage 13, and T objects can be sufficiently dried and incinerated in combustion stage 12 as needed . Since T objects having a high water content are transported to the combustion stage 12 while being dried without remaining in the drying stage 11, the T objects are also sufficiently incinerated in the combustion stage 12.

[095] As a result, regardless of the properties of T objects, it is possible to continuously load T objects, and it is possible to eliminate combustion residues from T objects.

[096] In addition, the end portion 13c of the post-combustion stage 13 on the downstream side in the direction of transport is located

substantially in the same position in the vertical direction as the end portion 12c of the combustion stage 12 on the downstream side in the transport direction, or above the end portion 12c of the combustion stage 12. Consequently, even in the case where the T objects roll down or the like in the drying stage 11, it is possible to prevent the T objects from being discharged from the post-combustion stage 13 without being sufficiently burned. Second Mode

[097] Next, a mechanical charger type incinerator according to a second embodiment of the present invention will be described in detail with reference to the drawings. In this modality, differences from the first modality described above will be mainly described, and the description of similar portions will be omitted.

[098] As illustrated in Figure 7, there is no step (descending wall) between the combustion stage 12 and the post-combustion stage 13 of the mechanical loader 5 of this modality. That is, the combustion stage 12 and the post-combustion stage 13 of this embodiment are continuously connected to each other. In other words, the end portion 12c of the combustion stage 12 on the downstream side in the transport direction and the end portion 13b of the post-combustion stage 13 on the upstream side in the transport direction are formed to have the same height .

[099] According to the modality, even if the T objects that roll down in the drying stage 11 have a strong moment and pass through the combustion stage 12 with their moment, it stops at least in the afterburn stage 13 and it is not discharged from the post-combustion stage 13. Furthermore, since the post-combustion stage 13 and the combustion stage 12 are continuously connected to each other without steps, even if the T objects, which are not sufficiently burnt, roll to the post-combustion stage

13, T objects return to combustion stage 12 due to their own weight, and combustion can be carried out. In other words, it is possible to reduce the discharge of incompletely burned T objects.

[0100] Although the modalities of the present invention have been described in detail with reference to the drawings, specific configurations are not limited to this modality, and changes in design and the like within the scope do not deviate from the essence of the present invention are included.

[0101] In the above modality, the distal ends of the fire grilles 15 and 16 are arranged towards the face of the downstream side D1 in the direction of transport. However, the present invention is not limited to it. For example, the distal ends of the fire grilles 15 and 16 of the drying stage 11 can be arranged towards the face of the upstream side in the direction of transport.

LIST OF REFERENCE SIGNS 1 MECHANICAL CHARGER TYPE INCINERATOR 2 FUNNEL 3 INCINERATION OVEN 4 MECHANICAL CHARGER 6 AIR BOX 7 FEED TABLE 8 FUEL DRIVING DEVICE 9 FUEL CHAMBER 11 FUEL FAN 11 DRYING STAGE 12 COMBUSTION STAGE 12a COMBUSTION STAGE INSTALLATION SURFACE

13 POST-COMBUSTION STAGE 13a POST-COMBUSTION STAGE INSTALLATION SURFACE 15 FIXED FIRE GRID 16 MOBILE FIRE GRID 16P SURFACE FIRE GRID 17 GRAY OUTPUT 18 DRIVE MECHANISM 19 WINDOWS 21 WINDOWS 20 WIRES 25 FIRE GRID BODY 26 PROJECTION 27, 28 STEP (WALL DOWN)

D TRANSPORT DIRECTION D1 DOWNWARD SIDE IN TRANSPORT DIRECTION

T OBJECT TO BE INCINERATED 1, 2, 3 MECHANICAL CHARGER TILTING ANGLE

Claims (8)

1. Mechanical loader type incinerator to burn objects to be incinerated, CHARACTERIZED by the fact that it comprises: a drying stage, a combustion stage and a post-combustion stage, each stage having a plurality of fixed fire grills and a plurality of mobile fire grills, and in which the objects to be incinerated supplied from a feeder are subjected to drying, combustion and post-combustion while sequentially transporting the objects to be incinerated through the drying stage, the combustion and the post-combustion stage, where the drying stage is arranged to be tilted so that a downstream side in a transport direction is directed downwards, the combustion stage is connected to the drying stage and arranged to be tilted so that the end of the downstream side in the direction of transport is directed upward, and the post-combustion stage is connected to the combustion stage and arranged to be tilted so that the end of the downstream side of it in the direction of transport is directed upward, with an end portion of the post-combustion stage on the downstream side in the direction of transport it is arranged in a vertical direction in the same position as the end portion of the combustion stage on the downstream side in the direction of transport, or in a higher position than the end portion of the combustion stage. 2. Mechanical loader type incinerator to burn the objects to be incinerated, according to claim 1, CHARACTERIZED by the fact that each of the fixed fire grills and mobile fire grills are willing to be tilted so that the end of the downstream side of it in the direction of transport is directed upwards in relation to the installation surfaces of the drying stage, the combustion stage, and the post-combustion stage. 3. Mechanical loader type incinerator to burn the objects to be incinerated, according to claim 2, CHARACTERIZED by the fact that the drying stage, the combustion stage, and the post-combustion stage each have a drive configured to drive the plurality of included mobile fire grills, and drive speeds in the drying stage, in the combustion stage, and in the post-combustion stage are set to the same or different speed in at least one of the drying stage, combustion stage, and post-combustion stage in relation to each other. 4. Mechanical loader-type incinerator to burn the objects to be incinerated, according to claim 3, CHARACTERIZED by the fact that the combustion stage and the post-combustion stage are continuously connected to each other without steps. 5. Mechanical loader-type incinerator to burn the objects to be incinerated, according to claim 3 or 4, CHARACTERIZED by the fact that at least one of the plurality of mobile fire grills of the drying stage is a protruding fire grate in that a protrusion is formed at the distal end of the protruding fire grid. 6. Mechanical loader type incinerator to burn the objects to be incinerated, according to claim 5, CHARACTERIZED by the fact that at least one of the plurality of mobile fire grills of the combustion stage is a protruding fire grate in that a protrusion is formed at the distal end of the protruding fire grid. 7. Mechanical loader type incinerator to burn the objects to be incinerated, according to claim 6, CHARACTERIZED by the fact that an angle of inclination of the mechanical loader of the drying stage is arranged at an angle between -15º and -25º, the angle of inclination of the mechanical loader of the combustion stage is arranged at an angle between + 8º and + 12º, and the angle of inclination of the mechanical loader of the post-combustion stage is the same as that of the combustion stage. 8. Mechanical loader type incinerator to burn the objects to be incinerated, according to claim 7, CHARACTERIZED by the fact that the angle of inclination of the mechanical loader of the drying stage is -20º, and the angle of inclination of the mechanical loader the combustion stage is + 10º.