KR102517623B1 - Actuating Apparatus for Moving Grate Improved Air Contact Area - Google Patents

Abstract

A moving grate actuating apparatus for improving an air contact area of the present invention, which can increase combustion efficiency, comprises: a plurality of fixed grate layers (10) which are installed inside a grate furnace, are horizontally arranged by forming step-like layers, and are disposed to be spaced apart from each other; a plurality of moving grate layers (20) which are disposed between the fixed grate layers (10), respectively, and are horizontally arranged by forming step-like layers; and a plurality of forward and backward moving means (30) which move each of the moving grate layers (20) forward and backward. The moving grate layers (20) is provided to have each layer in which unit moving grates (21) having a certain horizontal width are divided into a plurality of rows. When the unit moving grate (21) of the moving grate layer (20) in an odd-numbered row moves forward, the unit moving grate (21) of the moving grate layer (20) in an even-numbered row moves backward, to be alternately actuated.

Description

Actuating Apparatus for Moving Grate Improved Air Contact Area}

The present invention relates to a fluidized grate driving device for improving the air contact area for improving combustion efficiency by allowing horizontal movement of fluidized grates alternately adjacent to each other to improve the air contact area of wastes moved by this.

In general, an incineration facility includes a fluidized grate driving device in which a plurality of fixed grate arrays and a plurality of fluidized grate arrays are alternately installed in a stepwise manner so that waste is continuously moved and incinerated by the horizontal movement of the fluidized grate.

This fluidized grate driving device allows the waste to be continuously moved by the horizontal movement of the fluidized grate array by falling from the fixed grate array located on the upper side to the fixed grid array located on the lower side.

When the waste is dropped from the fixed grate array located on the upper side to the fixed grate array located on the lower side by the horizontal movement of the fluidized grate array, the entire waste located on the upper side falls to the lower side. realization becomes difficult.

Accordingly, the incineration facility can increase the combustion efficiency as the number of layers of the fixed grate array and the fluidized grate array increases. When the number of layers of the fixed grate arrangement and the fluidized grate arrangement increases, the height of the incineration facility increases and the length of the incineration facility also increases accordingly. In this way, in order to increase the combustion efficiency, the size of the incineration equipment is increased, and the equipment cost is increased.

Therefore, there is a demand for development of a fluidized grate driving device capable of miniaturizing an incineration facility as well as increasing combustion efficiency.

The present invention has been made to solve the above problems, and an object of the present invention is to improve the air contact area to improve the air contact area so as to increase the combustion efficiency and to miniaturize the incineration equipment. It is to provide a fluidized grate driving device.

In order to achieve the above object, the fluidized grate driving device for improving the air contact area of the present invention is installed inside the grate furnace, arranged horizontally in a stepwise layer, and a plurality of fixed grates arranged spaced apart from each other layer 10; a plurality of fluidized grating layers 20 each disposed between the fixed grating layers 10 and arranged horizontally in a stepwise manner; A plurality of fluidized grid layer forward and backward means 30 for moving each of the fluidized grid layers 20 forward and backward, and the fluidized grid layer 20, each layer has a certain width horizontally The unit fluidization grid 21 is provided by being divided into a plurality of rows, and each of the fluidization grid layer forward and backward means 30 is located at the rear end of the unit fluidization grid 21 of each fluidization grid layer 20. A fixed unit fluidized grid fixing rod 31, horizontally installed at the rear of the fluidized grid layer 20 in parallel thereto, and the unit fluidized grid fixed rod 31 of odd-numbered rows of each fluidized grid layer 20 ) and the horizontal connecting rod 32a for the first unit fluidization grid fixing rod connecting each of the fluidization grid layers 20 and horizontally installed in parallel to the rear of the fluidization grid layer 20, and each of the even numbers of the fluidization grid layer 20 The horizontal connecting rods 32b for the second unit fluidized grate fixed rods connecting the unit fluidized grate fixed rods 31 of the row, respectively, are installed in the same forward and backward direction of the fluidized grate layer 20, and the first The first and second pistons 34a and 34b coupled to the connecting rods 32a and 32b for the two-unit fluidized grate fixed rod, respectively, and the first and second pistons 34a and 34b driven to slide, It consists of two cylinders (35a, 35b), and the first and second cylinders (35a, 35b), when the unit fluidization grid 21 of the fluidization grid layer 20 in odd rows advances, the fluidization grid layer in even rows It is characterized in that the first and second pistons 34a and 34b are driven to slide alternately with each other so that the unit fluidized grate 21 of (20) moves backward.

In addition, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b of each of the fluidized grating layer forward and backward means 30 are formed as one, and the first and second pistons (34a, 34b) are characterized in that they are coupled to the central portion of the horizontal connecting rods (32a, 32b) for the first and second unit fluidized grate fixing rods.

In addition, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b of each of the fluidized grating layer forward and backward means 30 are formed as a left and right pair, respectively, and the first piston (34a) is coupled to both ends of the horizontal connecting rod 32a for the first unit fluidized grate fixed rod, respectively, and the second piston 34b is the horizontal connecting rod 32b for the second unit fluidized grate fixed rod. ) characterized in that it is coupled to both ends of each.

Another type of fluidized grate driving device for improving the air contact area according to the present invention is installed inside the grate furnace, and is arranged horizontally in a stepwise manner and is spaced apart from each other. A plurality of fixed grate layers (10 ); a plurality of fluidized grating layers 20 each disposed between the fixed grating layers 10 and arranged horizontally in a stepwise manner; A plurality of fluidized grid layer forward and backward means 30 for moving each of the fluidized grid layers 20 forward and backward, and the fluidized grid layer 20, each layer has a certain width horizontally The unit fluidization grid 21 is provided by being divided into a plurality of rows, and each of the fluidization grid layer forward and backward means 30 is located at the rear end of the unit fluidization grid 21 of each fluidization grid layer 20. A fixed unit fluidized grid fixing rod 31, horizontally installed at the rear of the fluidized grid layer 20 in parallel thereto, and the unit fluidized grid fixed rod 31 of odd-numbered rows of each fluidized grid layer 20 ) and the horizontal connecting rod 32a for the first unit fluidization grid fixing rod connecting each of the fluidization grid layers 20 and horizontally installed in parallel to the rear of the fluidization grid layer 20, and each of the even numbers of the fluidization grid layer 20 Horizontal connecting rods 32b for the second unit fluidized grate fixed rods connecting the unit fluidized grate fixed rods 31 of the row, respectively, and provided at the rear of the fluidized grid layer 20 of two to five layers adjacent to each other The vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods installed vertically with the first and second unit fluidized grate fixing rods 32a and 32b and connecting them to each other, and the fluidization It is installed in the same direction as the forward and backward direction of the grating layer 20, and the horizontal connecting rods 32a and 32b for the first and second unit fluidized grate fixed rods or the vertical connecting rods 33a for the first and second unit fluidized grate fixed rods , 33b) and the first and second pistons 34a and 34b coupled to each other, and the first and second cylinders 35a and 35b that drive the first and second pistons 34a and 34b to slide, The first and second cylinders 35a and 35b, when the unit fluidization grid 21 of the fluidization grid layer 20 of odd-numbered rows advance, the unit fluidization grid 21 of the fluidization grid layer 20 of even-numbered rows It is characterized in that the first and second pistons 34a and 34b are driven so as to slide alternately with each other so as to move backward.

In addition, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b of each of the fluidized grid layer forward and backward means 30 are formed as one, and the first and second pistons (34a, 34b) are characterized in that they are coupled to the central portion of the vertical connecting rods (33a, 33b) for the first and second unit fluidized grate fixing rods located at the central portion.

In addition, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b of each of the fluidized grating layer forward and backward means 30 are formed as a pair of left and right, respectively, The two pistons 34a and 34b are coupled to the central portions of the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods, respectively, located at both end portions.

The fluidization grid driving device for improving the air contact area of the present invention according to the configuration as described above is such that unit fluidization grids having a certain width across the fluidization grid layer are divided into a plurality of rows, and the unit fluidization grids of odd rows are advanced. Unlike the conventional fluidized grate driving device in which the entire solid fuel is dropped at once from the upper fixed grate layer to the lower fixed grate layer by driving the unit fluidized grate in even rows alternately, Since it falls down, the air contact area is improved, and thus complete combustion can be rapidly performed, thereby increasing combustion efficiency. In addition, as the number of floors of the stairs can be reduced compared to conventional devices, the height of the incineration equipment can be lowered and the length can be reduced, thereby miniaturizing the device and reducing equipment costs accordingly.

1 is a view showing an incineration facility in which a fluidized grate driving device for improving the air contact area of the present invention is installed.
2 and 3 are perspective views showing a fluidized grate driving device for improving the air contact area of the present invention.
4 and 5 are views showing a state of use of the fluidized grate driving device for improving the air contact area of the present invention.
6 and 7 are perspective views showing another type of fluidized grate driving device for improving the air contact area according to the present invention.
8 and 9 are views showing a state of use of a fluidized grate driving device for improving the air contact area of another type according to the present invention.

Hereinafter, the fluidized grate driving device for improving the air contact area of the present invention will be described in detail with reference to the drawings.

1 is a view showing an incineration facility in which a fluidized grate driving device for improving the air contact area of the present invention is installed, and FIGS. 2 and 3 are perspective views showing a fluidized grate driving device for improving the air contact area of the present invention. 4 and 5 are views showing the state of use of the fluidized grate driving device for improving the air contact area of the present invention.

The fluidization grid driving device for improving the air contact area according to the present invention is a fixed grid layer 10, a fluidized grid layer 20, and a fluidized grid layer forward and backward means 30 for moving the fluidized grid layer 20 forward and backward. );

As shown in FIG. 1, the fixed grate layers 10 are installed inside the grate furnace 1, and a plurality of them are arranged horizontally in a stepwise manner and spaced apart from each other to form a layer. The fixed grate layer 10 is in the form of a plate.

As shown in FIG. 1, the fluidized grating layers 20 are each disposed between the fixed grating layers 10 and are layered in a stepwise manner like the fixed grating layer 10, as shown in FIGS. 2 to 5, Many are arranged horizontally. The fluidized grating layer 20 is also in the form of a plate like the fixed grating layer 10.

In addition, in the fluidized grid layer 20, unit fluidized grids 21 each of which has a certain width horizontally are divided into a plurality of rows.

The fluidized grate layer forward and backward means 30 moves the fluidized grate layer 20 forward and backward so that the solid fuel located on the upper part of the fixed grate layer 10 is cascaded to each of the fixed grate layers 10 It serves to gradually move the solid fuel downward by allowing it to fall to the fixed grate layer 10 located at the lower portion adjacent thereto, and is made up of a plurality of as many as the number of fluidized grate layers.

At this time, the fluidized grate layer forward and backward means 30, as shown in FIGS. 2 to 5, the unit fluidized grate fixed rod 31, the first unit fluidized grate fixed rod for the horizontal connecting rod 32a, It consists of a horizontal connecting rod (32b) for a two-unit fluidized grate fixed rod, first and second pistons (34a and 34b), and first and second cylinders (35a and 35b).

In the drawings, only one layer of the fluidized grating layer 20 is shown.

The unit fluidized grate fixing rod 31 is fixed to the rear end of the unit fluidized grate 21 of each fluidized grate layer 20.

The horizontal connecting rod 32a for the first unit fluidization grid fixing rod is horizontally installed in parallel with the rear portion of the fluidization grid layer 20, and the unit fluidization of odd rows of each fluidization grid layer 20 The lattice fixing rods 31 are connected to each other.

The horizontal connecting rod 32b for the second unit fluidization grid fixing rod is horizontally installed in parallel with the rear portion of the fluidization grid layer 20, and the unit fluidization of the even-numbered rows of each fluidization grid layer 20 The lattice fixing rods 31 are connected to each other.

At this time, in order to prevent interference between the horizontal connecting rod 32a for the first unit fluidized grate fixed rod and the horizontal connecting rod 32b for the second unit fluidized grate fixed rod overlap each other, each of the fluidized grate The unit fluidization grid fixing rods 31 of odd-numbered rows of layers 20 and the unit fluidization grid fixing rods 31 of even-numbered rows of each fluidization grid layer 20 may have different lengths, and each of the fluidization grids may have different lengths. The heights of the unit fluidized grid fixing rods 31 in odd-numbered rows of the grid layer 20 and the unit fluidized grid fixed rods 31 in even-numbered rows of each fluidized grid layer 20 may be different.

The first and second pistons 34a and 34b are installed in the same forward and backward direction of the fluidized grate layer 20, and are connected to the first and second unit fluidized grate fixed rod connecting rods 32a and 32b, respectively. are combined

The first and second cylinders 35a and 35b serve to drive the first and second pistons 34a and 34b to slide.

At this time, the first and second cylinders 35a and 35b, when the unit fluidization grid 21 of the fluidization grid layer 20 in odd rows advances, the unit fluidization grid of the fluidization grid layer 20 in even rows ( 21) is driven so that the first and second pistons 34a and 34b slide alternately with each other so as to move backward. Contrary to this, the first and second cylinders 35a and 35b, when the unit fluidization grid 21 of the fluidization grid layer 20 in odd rows moves backward, the unit fluidization grid of the fluidization grid layer 20 in even rows The first and second pistons 34a and 34b are driven to slide alternately with each other so that (21) moves forward.

In this way, when the first and second cylinders 35a and 35b advance the unit fluidization grid 21 of the fluidization grid layers 20 in odd rows, the unit fluidization of the fluidization grid layers 20 in even rows When the first and second pistons 34a and 34b are driven to slide alternately with each other so that the grate 21 moves backward, the entire solid fuel falls from the upper fixed grate layer to the lower fixed grate layer at once Unlike the conventional fluidized grate driving device that is used, since the solid fuel layer is divided into a plurality of units and dropped by a plurality of unit fluidized grate 21, the air contact area of the solid fuel layer is improved, thereby preventing complete combustion. It can proceed quickly, which can increase the combustion efficiency. In addition, as the number of floors of the stairs can be reduced compared to conventional devices, the height of the incineration equipment can be lowered and the length can be reduced, thereby miniaturizing the device and reducing equipment costs accordingly.

In the present invention, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b provided in each fluidized grating layer 20 may be provided as one, respectively, and each pair is left and right. may be provided.

When the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b provided in each fluidized grating layer 20 are provided as one, the first and second pistons 34a, 34b) is coupled to the central portion of the horizontal connecting rods 32a and 32b for the first and second unit fluidized grate fixing rods, respectively, and is connected to the first and second cylinders 35a and 35b, respectively. , so that the two pistons 34a and 34b slide and drive. In the drawings, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b are provided as one.

When the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b provided on each fluidized grating layer 20 are provided on the left and right as a pair (not shown), The first piston (34a) is coupled to both ends of the horizontal connecting rod (32a) for the first unit fluidized grate fixing rod, respectively, and the second piston (34b) is horizontal for the second unit fluidized grate fixing rod. They are coupled to both ends of the connecting rod 32b, and the pair of first and second pistons 34a and 34b are slidingly driven by the pair of first and second cylinders 35a and 35b, respectively.

At this time, the left and right pair of first and second cylinders 35a and 35b allow the first and second pistons 34a and 34b to be slidingly driven at the same stroke distance, and the unit of the fluidized grid layer 20 in an odd number row When the fluidization grid 21 moves forward, the unit fluidization grid 21 of the even-numbered rows of the fluidization grid layer 20 moves backward, so that the fluidization grid 21 is driven alternately with each other.

In the present invention, it is preferable that the sliding stroke speed of the first and second pistons 34a and 34b by the first and second cylinders 35a and 35b gradually increases toward the bottom.

The reason why the sliding stroke speed of the first and second pistons 34a and 34b by the first and second cylinders 35a and 35b gradually increases toward the bottom is that the combustion of solid fuel gradually increases from the top to the bottom. It is done less, so it is to match the burning rate and amount.

6 and 7 are perspective views showing another type of fluidized grate driving device for improving the air contact area according to the present invention, and FIGS. 8 and 9 are different types of fluidized grate driving device for improving the air contact area according to the present invention. It is a drawing showing the state of use of the device.

Another type of fluidized grate driving device for improving the air contact area according to the present invention allows two to five fluidized grate layers adjacent to each other to move forward and backward simultaneously, and the above-described fluidized grate for improving the air contact area according to the present invention As with the driving device, the odd-numbered column unit fluidized gratings and the even-numbered column unit fluidized gratings are alternately moved back and forth.

The fluidization grating driving device for improving the air contact area of another type according to the present invention, like the above-described fluidization grating driving device for improving the air contact area according to the present invention, includes a fixed grating layer 10 and a fluidized grating layer 20 ) and a fluidized grid layer forward and backward means 30 for moving the fluidized grid layer 20 forward and backward.

The fixed grating layer 10 and the fluidized grating layer 20 of the other type of fluidized grating driving device for improving the air contact area according to the present invention are the same as the fluidized grating driving device for improving the air contact area according to the present invention described above. do.

As shown in FIG. 1, the fixed grate layers 10 are installed inside the grate furnace 1, and a plurality of them are arranged horizontally in a stepwise manner and spaced apart from each other to form a layer. The fixed grate layer 10 is in the form of a plate.

As shown in FIG. 1, the fluidized grating layers 20 are each disposed between the fixed grating layers 10 and are layered in a stepwise manner like the fixed grating layer 10, as shown in FIGS. 6 to 9 , many of which are arranged horizontally. The fluidized grid layer 20 is also in the form of a plate like the fixed grid layer 10.

In addition, in the fluidized grid layer 20, unit fluidized grids 21 each of which has a certain width horizontally are divided into a plurality of rows.

The fluidized grate layer forward and backward means 30 moves the fluidized grate layer 20 forward and backward so that the solid fuel located on the upper part of the fixed grate layer 10 is cascaded to each of the fixed grate layers 10 It serves to gradually move the solid fuel to the lower portion by allowing it to fall to the fixed grate layer 10 located at the lower portion adjacent thereto.

For example, the fluidized grid layer 20 has a total of 30 layers, and the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods to be described later are for the first and second unit fluidized grate fixed rods of the three layers. If the horizontal connecting rods 32a and 32b are connected, the fluidized grating layer forward and backward means 30 may be provided in 10 pieces.

As shown in FIGS. 6 and 9, each of the fluidized grate layer forward and backward means 30 includes a unit fluidized grate fixed rod 31, a horizontal connecting rod 32a for the first unit fluidized grate fixed rod, The horizontal connecting rod (32b) for the 2 unit fluidized grate fixed rod, the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixed rods, the first and second pistons 34a and 34b, the first, It consists of two cylinders (35a, 35b).

The figure shows a structure in which the unit fluidization grids 21 of odd-numbered or even-numbered columns of the three fluidized grid layers 20 are simultaneously alternately moved horizontally.

The unit fluidized grate fixing rod 31 is fixed to the rear end of the unit fluidized grate 21 of each unit fluidized grate layer 20.

The horizontal connecting rod 32a for the first unit fluidization grid fixing rod is horizontally installed in parallel with the rear portion of the fluidization grid layer 20, and the unit fluidization of odd rows of each fluidization grid layer 20 The lattice fixing rods 31 are connected to each other.

The horizontal connecting rod 32b for the second unit fluidization grid fixing rod is horizontally installed in parallel with the rear portion of the fluidization grid layer 20, and the unit fluidization of the even-numbered rows of each fluidization grid layer 20 The lattice fixing rods 31 are connected to each other.

At this time, in order to prevent interference between the horizontal connecting rod 32a for the first unit fluidized grate fixed rod and the horizontal connecting rod 32b for the second unit fluidized grate fixed rod overlap each other, each of the fluidized grate The unit fluidization grid fixing rods 31 of odd-numbered rows of layers 20 and the unit fluidization grid fixing rods 31 of even-numbered rows of each fluidization grid layer 20 may have different lengths, and each of the fluidization grids may have different lengths. The heights of the unit fluidized grid fixing rods 31 in odd-numbered rows of the grid layer 20 and the unit fluidized grid fixed rods 31 in even-numbered rows of each fluidized grid layer 20 may be different.

The vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods are fixed to the first and second unit fluidized grates provided at the rear of the fluidized grate layers 20 of two to five layers adjacent to each other. It is installed vertically with the horizontal connecting rods 32a and 32b for rods and connects them to each other. At this time, it is preferable that the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixed rods be inclined at the same angle as the slope of the fixed grate layer 10 provided in a stepwise manner.

When the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods are installed upright, the first and second unit fluidized grate fixing rods provided at the rear of the unit fluidized grate 21 located at the top The length of the horizontal connecting rods 32a and 32b for the first and second unit fluidized grate fixed rods provided at the rear of the unit fluidized grate 21 located at the lower part is longer than the length of the horizontal connecting rods 32a and 32b for When the unit fluidized grate 21 is moved back and forth by the sliding of the first and second pistons 34a and 34b to be described later, the force for the forward and backward movement of the unit fluidized grate 21 located at the top More force is required for the forward and backward movement of the unit fluidized grate 21 located lower than that, and thus an imbalance of force may occur.

When the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixed rods are installed inclined at the same angle as the slope of the fixed grate layer 10 provided in a stepwise manner, the unit fluidized grate located on the upper part ( 21), the length of the horizontal connecting rods 32a and 32b for the first and second unit fluidized grate fixing rods provided at the rear, and the first and second units provided at the rear of the unit fluidized grate 21 located at the bottom The horizontal connecting rods 32a and 32b for the fixed rods of the fluidized grate can have the same length, so that the unit fluidized grate 21 moves back and forth by the sliding of the first and second pistons 34a and 34b, which will be described later. When the unit fluidized grate 21 located at the top and the front and rear movement of the unit fluidized grate 21 located at the bottom require the same force, the force is balanced to achieve the first The sliding of the first and second pistons 34a and 34b allows the unit fluidized grate 21 to move smoothly back and forth.

The first and second pistons 34a and 34b are installed in the same forward and backward direction of the fluidized grate layer 20, and the horizontal connecting rods 32a and 32b for the first and second unit fluidized grate fixing rods or It is coupled to the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods, respectively.

The first and second cylinders 35a and 35b serve to drive the first and second pistons 34a and 34b to slide.

At this time, the first and second cylinders 35a and 35b, when the unit fluidization grid 21 of the fluidization grid layer 20 in odd rows advances, the unit fluidization grid of the fluidization grid layer 20 in even rows ( 21) is driven so that the first and second pistons 34a and 34b slide alternately with each other so as to move backward. Contrary to this, the first and second cylinders 35a and 35b, when the unit fluidization grid 21 of the fluidization grid layer 20 in odd rows moves backward, the unit fluidization grid of the fluidization grid layer 20 in even rows The first and second pistons 34a and 34b are driven so as to slide alternately with each other so that (21) moves forward.

In this way, when the first and second cylinders 35a and 35b advance the unit fluidization grid 21 of the fluidization grid layers 20 in odd rows, the unit fluidization of the fluidization grid layers 20 in even rows When the first and second pistons 34a and 34b are driven to slide alternately with each other so that the grate 21 moves backward, the entire solid fuel falls from the upper fixed grate layer to the lower fixed grate layer at once Unlike the conventional fluidized grate driving device that is used, since the solid fuel layer is divided into a plurality of units and dropped by a plurality of unit fluidized grate 21, the air contact area of the solid fuel layer is improved, thereby preventing complete combustion. It can proceed quickly, which can increase the combustion efficiency. In addition, as the number of floors of the stairs can be reduced compared to conventional devices, the height of the incineration equipment can be lowered and the length can be reduced, thereby miniaturizing the device and reducing equipment costs accordingly.

In addition, the first and second unit fluidized grates provided at the rear of the fluidized grate layers 20 of 2 to 5 layers in which the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods are adjacent to each other. By connecting the horizontal connecting rods 32a and 32b for fixed rods to each other, the unit fluidized grate 21 of the fluidized grate layer 20 of 2 to 5 layers can be moved back and forth at the same time, so that the above-described present invention Compared to the fluidized grid driving device for improving the air contact area, the number of the first and second cylinders 35a and 35b and the first and second pistons 34a and 34b can be reduced.

In addition, in the present invention, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b provided in each fluidized grating layer 20 may be provided as one, respectively, as a pair. It can be provided on the left and right.

When the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b provided in each fluidized grating layer 20 are provided as one, the first and second pistons 34a , 34b) is coupled to the central portion of the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods located in the central portion, respectively, to the first and second cylinders 35a and 35b by which the first and second pistons 34a and 34b are slidingly driven. In the drawings, the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b are provided as one.

When the first and second pistons 34a and 34b and the first and second cylinders 35a and 35b provided on each fluidized grating layer 20 are provided on the left and right as a pair (not shown), The first and second pistons 34a and 34b are coupled to the central portion of the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixing rods, respectively, located at both end portions, and the pair of first and second pistons 34a and 34b The first and second pistons 34a and 34b are slidingly driven by the pair of first and second cylinders 35a and 35b, respectively.

At this time, the left and right pair of first and second cylinders 35a and 35b allow the first and second pistons 34a and 34b to be slidingly driven at the same stroke distance, and the unit of the fluidized grid layer 20 in an odd number row When the fluidization grid 21 moves forward, the unit fluidization grid 21 of the even-numbered rows of the fluidization grid layer 20 moves backward, so that the fluidization grid 21 is driven alternately with each other.

In the present invention, it is preferable that the sliding stroke speed of the first and second pistons 34a and 34b by the first and second cylinders 35a and 35b gradually increases toward the bottom.

The reason why the sliding stroke speed of the first and second pistons 34a and 34b by the first and second cylinders 35a and 35b gradually increases toward the bottom is that the combustion of solid fuel gradually increases from the top to the bottom. This is to match the burning rate and amount because it is done less.

Technical ideas should not be interpreted as being limited to the above-described embodiments of the present invention. Not only the scope of application is diverse, but also various modifications and implementations are possible at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, such improvements and changes fall within the protection scope of the present invention as long as they are obvious to those skilled in the art.

1: Grate furnace
10: fixed grate layer
20: fluidized grid layer
21: unit fluidized grate
30: fluidized grid layer forward and backward means
31: unit fluidized grate fixed rod
32a, 32b: horizontal connecting rod for the first and second unit fluidized grate fixed rods
33a, 33b: Vertical connecting rods for the first and second unit fluidized grate fixed rods
34a, 34b: first and second pistons
35a, 35b: first and second cylinders

Claims (6)

delete delete delete delete delete A plurality of fixed grate layers (10) installed inside the grate furnace, arranged horizontally in a stepwise layer and spaced apart from each other;
a plurality of fluidized grating layers 20 each disposed between the fixed grating layers 10 and arranged horizontally in a stepwise manner;
A plurality of fluidized grid layer forward and backward means 30 for moving each of the fluidized grid layers 20 forward and backward,
The fluidized grid layer 20 is provided with a unit fluidized grid 21, each layer having a certain width horizontally, divided into a plurality of rows,
Each of the fluidized grating layer forward and backward means 30,
A unit fluidization grid fixing rod 31 fixed to the rear end of the unit fluidization grid 21 of each fluidization grid layer 20;
A first unit fluidized grate fixing rod that is horizontally installed at the rear of the fluidized grate layer 20 in parallel thereto and connects the unit fluidized grate fixing rods 31 of odd-numbered rows of each of the fluidized grate layers 20, respectively. For a horizontal connecting rod (32a),
Second unit fluidization grid fixing rods installed horizontally in parallel to the rear of the fluidization grid layer 20 and connecting the unit fluidization grid fixing rods 31 of even-numbered rows of each of the fluidization grid layers 20, respectively For a horizontal connecting rod (32b),
Installed vertically with the horizontal connecting rods 32a and 32b for the first and second unit fluidized grate fixing rods provided at the rear of the fluidized grate layer 20 of two to five layers adjacent to each other, and connecting them to each other. , vertical connecting rods 33a and 33b for 2 unit fluidized grate fixed rods,
It is installed in the same direction as the forward and backward direction of the fluidized grate layer 20, and the horizontal connecting rods 32a and 32b for the first and second unit fluidized grate fixed rods or the vertical connecting rods for the first and second unit fluidized grate fixed rods First and second pistons 34a and 34b coupled to (33a and 33b), respectively;
It consists of first and second cylinders 35a and 35b that drive the first and second pistons 34a and 34b to slide,
The first and second cylinders 35a and 35b, when the unit fluidization grid 21 of the fluidization grid layer 20 of odd-numbered rows advance, the unit fluidization grid 21 of the fluidization grid layer 20 of even-numbered rows The first and second pistons 34a and 34b are driven so as to slide alternately with each other so as to move backward,
The first and second pistons 34a and 34b and the first and second cylinders 35a and 35b of each of the fluidized grating layer forward and backward means 30 are formed as a left and right pair, respectively,
The first and second pistons 34a and 34b are coupled to the central portion of the vertical connecting rods 33a and 33b for the first and second unit fluidized grate fixed rods, respectively, located at both end portions,
Each of the fluidized grate layers ( 20), the length of the unit fluidization grid fixing rods 31 of odd-numbered rows and the unit fluidization grid fixing rods 31 of even-numbered rows of each fluidization grid layer 20 may be different, or each of the fluidization grid layers 20 The unit fluidization grid fixing rods 31 of odd rows of ) and the unit fluidization grid fixing rods 31 of even rows of each of the fluidization grid layers 20 are different in height,
The sliding stroke speed of the first and second pistons 34a and 34b by the first and second cylinders 35a and 35b gradually increases as it goes downward. Fluidized grate driving device for improving air contact area.

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