BRPI1006054B1 - NARROW RADIATOR CART BRACKET - Google Patents

Description

(54) Title: TROLLEY SUPPORT BEAM FOR ANNULAR RADIATOR (51) Int.CI .: F27B 21/08 (30) Unionist Priority: 10/02/2009 CN 200910005655.7 (73) Holder (s): ZHONGYE CHANGTIAN INTERNATIONAL ENGINEERING CO., LTD.

(72) Inventor (s): DELIANG GAO; XIANGPEI LIU; QUING GUO; ZHEMING LIU

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Descriptive Report of the Invention Patent for: “CART BEAM SUPPORT FOR ANNULAR RADIATOR”.

This application claims the priority benefit of CN Patent Application No. 200910005655.7, entitled CART SUPPORT BEAM FOR ANNULAR RADIATOR filed on February 10, 2009 at the Chinese State Intellectual Property Office, which is incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to an annular radiator, in particular to a pallet support beam for an annular radiator.

BACKGROUND OF THE INVENTION

Referring to Fig. 1, a structural view of existing pallet support beams for an annular radiator is shown. The pallet support beams for the annular radiator are used to support the pallets. The pallet support beams are arranged in the radial direction of the annular radiator, with their cross sections (taken along the circumferential direction of the annular radiator) being in the shape of a triangle. Pallet support beams and grid plates 103 are used to support mineral material to be cooled and transported by the pallets. To solve the problem that the pallet support beams for an annular radiator are still stacked with mineral material on the top of it after the mineral material is discharged from these pallets, the existing pallet support beams for the annular radiator were designed in triangular beam structure.

The existing annular radiator makes a circular motion at a uniform speed, and the material is evenly loaded onto the pallets through a feed chute when the pallets pass through a loading area (having an area of several pallets). As the pallets loaded with material pass through an air-cooled area, the cooling air is blown upwards from the lower windboxes, then passes through grid plates 103, and is finally discharged through a duct. or directly into the atmosphere after heat exchange with the hot-sintered mineral material on the grid plates 103. Approximately one hour later, the hot-sintered mineral material is substantially cooled, and the pallets pass through an unloading area ( having an area of several pallets) where the pallet wheels 104 move along respective curved discharge rails (not shown), such that the pallet bodies 105 are rotated around the respective ball joints 106, and at the same time the grade 103 plates are angled downward, such that the mineral material on the grade 103 plates is discharged into a discharge chute (not shown). Furthermore, due to the two

2/13 side plates 102b of each triangular beam 102, the mineral material on the triangular beam 102 can slide downwardly along the side plates. Therefore, the sintered mineral material is discharged into the discharge chute, and the cooling process is completed. Thereafter, pallet wheels 104 are moved upwardly along respective curved replacement rails (not shown) (curved discharge rails and curved replacement rails constituting a set of consecutive curved rails), and pallet bodies 105 enter the loading area again after being repositioned in order to be loaded. The annular radiator is operated repeatedly.

The triangular beam of the conventional pallet support beam for the annular radiator includes two side plates 102b and a bottom plate. To ensure an excellent support effect of the pallet support beam for the annular radiator, the two side plates and the lower pallet support beam for the annular radiator are both blind plates.

When the annular radiator pallet is operated, the hot-sintered mineral material is completely loaded onto the grid plates 103 and the two side plates 102b of the support beam, and the cooling air is forcibly blown into the mineral layer upwardly through of the grid plates 103 to perform the heat exchange with the hot sintered mineral material, thereby cooling the mineral material. Since air always tends to pass through the region along a route having the minimum resistance and the shortest distance, when the cooling air is forcibly blown into the layer of mineral material upwardly through the grid plates 103, the largest part of the cooling air passes through a region A (referring to Fig. 1) above the grid plates 103, and is discharged through a duct or directly into the atmosphere from the surface of the upper part of the layer of mineral material after heat exchange with mineral material. Since the three plates constituting the triangular beam are all blind plates, only little or no cooling air enters a region B (in reference to Fig. 1) above the projection area of the lower plate of the triangular beam, and a dead material cooling region is formed.

Therefore, it is a technical problem to be solved by those skilled in the art to provide a pallet support beam for an annular radiator that can solve the problem of poor cooling effect for mineral material above the pallet support beam for the radiator. cancel.

SUMMARY OF THE INVENTION

In view of the prior disadvantages in the prior art, the object of the present invention is to provide a pallet support beam for an annular radiator that can improve the cooling effect for mineral material above the pallet support beam for the annular radiator and effectively protect the pallet's static sealing device.

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The object of the present invention is achieved by the following technical solutions:

The present invention provides a pallet support beam for an annular radiator to support the pallets of the annular radiator, which includes a rectangular beam and a triangular beam located on the rectangular beam. An upper flange plate of the rectangular beam is extended and extended towards both sides to form a lower triangular beam plate, and portions of the upper flange plate of the rectangular beam extending and expanding towards both sides are provided with air vents, and two side plates of the triangular beam, which join the lower plate of the triangular beam, are provided with a plurality of through holes. Two solid plates connected on their sides are provided on the upper flange plate of the rectangular beam, and there is a distance between the connected sides of the two solid plates and the lower plate of the triangular beam. The angles between the two solid plates and the horizontal plane are greater than or equal to the angle of rest of the mineral material to be cooled by the pallets of the annular radiator.

Preferably, the two solid plates are equal to the side plates of the triangular beam in length.

Preferably, the angles between the two solid plates and the horizontal plane are the same or not the same.

Preferably, the distances between the horizontal projections of the two solid plates and the air vents are preset to zero.

Preferably, the shape and cross-sectional area of the through holes are determined according to an established size of upper grid plates of the annular radiator pallets.

Preferably, the through holes are triangular, circular, elliptical, rectangular or polygonal holes.

Preferably, the through-holes have the same or different shapes.

Preferably, any of the side plates of the triangular beam includes a frame, and a grid plate device or a grid bar device or an orifice plate device that are mounted on the frame.

Preferably, the through holes in the grid plate device, the grid bar device or the orifice plate device are triangular, circular, elliptical, rectangular or polygonal holes. >

Preferably, the cross-sectional area of each air vent is greater than or equal to that of each through-hole, and the total area of the cross-sections of the air vents is greater than the total area of the cross-sections of the through-holes.

Preferably, any portion of the upper beam flap plate

Rectangular 4/13 extending and expanding towards both sides is provided with at least one air vent.

Preferably, the air vents provided in the upper flap plate portion of the rectangular beam extending and expanding towards both sides are independent of or are in communication with each other.

Preferably, the cross section of each air vent is circular, elliptical, triangular, rectangular or polygonal.

The pallet support beam for the annular radiator according to the present invention includes the rectangular beam and the triangular beam located on the rectangular beam. The upper flap plate of the rectangular beam is extended and extended towards both sides to form the lower plate of the triangular beam, and portions of the upper flange plate of the rectangular beam extending and expanding towards both sides are provided with air vents. The cooling air can enter the triangular beam through the air vents. Since the two side plates of the triangular beam, which join the lower plate of the triangular beam, are provided with a plurality of through holes, the cooling air having entered the triangular beam can still enter the region B shown in Fig. 2 through these through holes in order to cool the mineral material in region B. Therefore, the cooling effect for the mineral material above the pallet support beam for the annular radiator is improved.

Two solid plates connected on their sides are provided on the upper flange plate of the rectangular beam of the pallet support beam for the annular radiator according to the present invention, and there is a certain distance between the connected sides of the two solid plates and the bottom plate of the triangular beam. The two solid plates and the upper flap plate constitute an internal triangular beam. Mineral material falling through the through holes in the side plates of the triangular beam can slide downwardly along the two solid plates of the internal angular beam, then falls on the lower flat plate of the pallet through the air vents provided in the flap plate portions. top of the rectangular beam extending and widening towards both sides, thus mixing together with the mineral material falling through the gaps in the grid plates. When the pallet is unloaded, the mineral material having fallen on the lower flat plate of the pallet and the mineral material cooled on the grid plate are unloaded together in a discharge chute (not shown) in the discharge area. Therefore, the mineral material is effectively prevented from accumulating within the triangular beam. In addition, it is possible to avoid the form of accumulated material falling over the area between the static pallet sealing device and the sealing surface of the lower flat plate of the pallet when the pallet is repositioned after unloading, and thus the static sealing device and even the pallet are prevented from being damaged.

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BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a structural view of an existing support beam from a pallet to an annular radiator;

Fig. 2 is a structural view of a first embodiment of the pallet support beam for the annular radiator according to the present invention;

Fig. 3 is an enlarged view of the portion I shown in Fig. 2;

Fig. 4 is a top view of a second embodiment of the pallet support beam for the annular radiator according to the present invention;

Fig. 5 is a sectional view along the direction A-A shown in Fig. 4;

Fig. 6 is a sectional view along the C-C direction shown in Fig. 5. DETAILED DESCRIPTION OF THE INVENTION

The present invention provides a pallet support beam for an annular radiator to improve the cooling effect for mineral material above the pallet support beam for the annular radiator and effectively protect the static pallet sealing device.

The structure and operating principle of the pallet support beam for the annular radiator according to the present invention will be clearer from the specific description in conjunction with the following drawings.

Referring to Figs. 2 and 3, Fig. 2 is a structural view of a first embodiment of the pallet support beam for the annular radiator according to the present invention, and Fig. 3 is an enlarged view of the portion I shown in Fig. 2 .

The pallet support beam for the annular radiator according to the embodiment of the present invention is used to support the annular radiator pallet. The pallet support beam for the annular radiator includes a rectangular beam 1 and a triangular beam 2 located on the rectangular beam 1.

An upper flange plate of the rectangular beam 1 is extended and extended towards both sides to form a lower plate 21 of the triangular beam, and portions of the upper flange plate of the rectangular beam 1 extending and expanding towards both sides are provided with air vents 21a. Both sides of the lower plate 21 of the triangular beam join the grid plates 3, respectively. Grid plates 3 are used for ventilation and are upper grid plates on the pallet.

The portions of the upper flap plate of the rectangular beam extending and expanding towards both sides can be provided with a plurality of air vents 21a, respectively. The air vents 21a can be independent of or in communication with one another. The cross section of each air vent can be in the form of a circle, ellipse, triangle, rectangle or other polygons.

Two side plates 22 of the triangular beam, which are adjacent to the bottom plate 21 of the

6/13 triangular beam, can be directly provided with a plurality of small section through holes 22a which are densely arranged. The shape and cross-sectional area of the small section through holes 22a are determined according to the sizes of the upper grid plates of the annular radiator pallets. Generally, the size of the small section through holes 22a is predetermined within a range of 8 ~ 12 mm.

The small section through holes 22a can perform the ventilation function.

The shape of the small section through holes 22a can be circular, elliptical or polygonal. When the shape of the small section through holes 22a is circular, the diameter of the same is usually pre-established within a range of 8 ~ 12 mm.

When the annular radiator pallets are in operation, the hot-sintered mineral material 4 is completely loaded onto the grid plates 3 and the side plates 22 of the triangular beam, and the cooling air is forced upwardly through the grid plates 3 and the small section through holes 22a in the side plates 22 of the triangular beam in the layer of mineral material 4 to perform a heat exchange with the hot-sintered mineral material 4 in order to cool the mineral material 4.

Once the small section through holes 22a are provided in the side plates 22 of the triangular beam in order to further increase the ventilation area of the side plates 22 of the triangular beam, that is, to enlarge the total cooling area of the annular radiator, the amount of air per unit area in the annular radiator is decreased, and the average air speed is decreased. In addition, the resistance in mineral material 4 is decreased in direct proportion to 1.67 of the airspeed power (ie, P kv ^{1 '67} ). When the capacity of the cooling air duct to supply the cooling air is constant (that is, the total pressure value is constant), the resistance in the annular radiator is decreased, and thus the amount of air supplied from the fans will be increased. correspondingly. Thanks to the increased amount of air, mineral material 4 can be cooled better.

Since there is cooling air that passes through both the grid plates 3 and the side plates 22 of the triangular beams, the air velocity in the interior portion and on the surface of the layer of mineral material becomes more uniform. Thus, fly ash is consequently decreased, and the surrounding environment is improved.

However, there are partially loose material and powder material, which can fall into the inner portion of the triangular beam through the gap between the grid plates or grid bars of the triangular beam, or through the plate holes or through holes. A portion of the loose material and powder material falling into the inner portion of the triangular beam

7/13 will additionally fall on a lower flat plate of the pallet through the air vents 21a on the lower plate of the triangular beam, while another portion of them will be stacked in the area of the lower plate of the triangular beam where air ventilation is not provided. Usually, this loose material and powder material piled on the bottom plate 21 of the triangular beam will not fall. Since this loose material and powder material have a certain weight, and are mixed with the annular radiator for a long time, the load of the annular radiator in operation is increased. This loose material and powder material piled on the lower plate 21 of the triangular beam will be spread when the pallet is unloaded and repositioned, and in particular, when the pallet is repositioned after being unloaded, the scattered mineral material will fall on the lower flat plate of the pallet through the air vents 21a on the lower plate of the triangular beam, such that some material will be captured between the static sealing device of the pallet and the sealing surface of the lower flat plate of the pallet, which will cause damage to the sealing device static and even the pallet.

Therefore, an internal triangular beam 5 can be provided on the upper flange plate of the rectangular beam 1. The internal triangular beam 5 includes two solid plates 51, 52 which are connected with each other on its sides. There is a distance between the connected sides of the two solid plates 51, 52 and the lower plate 21 of the triangular beam. To ensure that the loose material and powder material on the inner triangular beam 5 can still slide smoothly along the inclined surfaces of the two solid plates 51, 52 of the inner triangular beam 5 on the lower flat plate of the pallet during the entire operation of the pallet , the angles between the two solid plates 51, 52 of the internal triangular beam 5 and the horizontal plane can be pre-established to be greater than or equal to an angle of rest of the mineral material to be cooled on the pallet of the annular radiator.

Thus, when a portion of loose material and powder material in the mineral material falls on the inner triangular beam 5 within the triangular beam through the small section passage holes 22a, this loose material and powder material will slide downwardly along the two plates solid 51.52 directly, and will additionally fall on the lower flat plate of the pallet through the air vents 21 to provided on the lower plate 21 of the triangular beam. At the same time, another portion of loose material and powder material on the pallet's grid plates 3 also falls on the pallet's lower flat plate through gaps on the grid plates. When the pallet is unloaded, the mineral material cooled on the lower flat plate of the pallet, the grid 3 plates of the pallet and the side plates 22 of the triangular beam will all be unloaded on the discharge chute (not shown) in the discharge area. The internal triangular beam 5 can effectively prevent the mineral material from stacking inside the triangular beam 2. For the reason that before the pallet is unloaded, loose material and powder material falling through the opening holes.

8/13 small section passage 22a on the side plates 22 of the triangular beam fell on the lower flat plate of the pallet under the guide of the internal triangular beam 5, there will be non-stacked material to be spread on the lower flat plate of the pallet during the replacement of the pallet. During the replacement of the pallet, it is ensured that there is no material to be captured between the sealing members of the static pallet seal, the frame of the sealing members and the sealing surface of the lower flat plate of the pallet, in order to prevent it from flowing. vfidaçao rtn palRtft rtnjn rinnifinaria pnr causes captured material, and also prevents the pallet from being damaged and other possible accidents caused by the captured material during the replacement of the pallet.

To better prevent the mineral material from being stacked inside the triangular beam 2, the inner triangular beam 5 can be the same length as the triangular beam 2. The two solid plates of the inner triangular beam 5 can be the same length as the side plates of the triangular beam 2.

In a long-lasting operation of the pallet, the through holes in the side plates 22 of the triangular beam will become larger because of the impact of the mineral material during loading, such that the larger size material will fall through the through holes. Because the angles between the two solid plates 51, 52 of the inner triangular beam 5 and the horizontal plane are greater than or equal to the angle of rest of the mineral material, the material with the largest size falling from the triangular beam will also fall smoothly on the lower flat plate of the pallet, without damaging the static sealing device or even the pallet, and without causing accidents during the replacement of the pallet after being unloaded.

Naturally, the angles between the two solid plates 51, 52 of the inner triangular beam 5 and the horizontal plane can be the same or not the same. Since the angles between the two solid plates 51,52 of the inner triangular beam 5 and the horizontal plane are greater than or equal to the angle of rest of the mineral material, it is possible to prevent the stacked material from falling over the area between the sealed surface of the lower flat plate of the pallet and the static pallet sealing device during the replacement of the pallet after being unloaded, in order to protect the static sealing device from being damaged.

It is required that the distance between the horizontal projections of the two solid plates 51, 52 of the internal triangular beam 5 and the air vents 21 a be pre-set to zero, in order to ensure that the mineral material falling from the triangular beam can slide gently on the lower flat plate of the pallet through the air vents 21a.

The positional relationship between the pallet support beam for the annular radiator according to the modalities of the present invention and the entire pallet of the annular radiator will be more clearly described together with Figs. 4 to 6 as follows.

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Referring to Figs. 4 to 6, Fig. 4 is a top view of a second embodiment of the pallet support beam for the annular radiator according to the present invention, Fig. 5 is a sectional view along the direction AA shown in Fig. 4, and Fig. 6 is a sectional view along the CC direction shown in Fig. 5.

The annular radiator includes a plurality of annular radiator pallets 100, which are arranged sequentially, equidistantly and concentrically, and are rotated in the same direction as shown in the figure at the same speed.

The pallet unloading process will be specifically described in conjunction with Fig. 6 as follows.

The wheels 100a of the pallets are moved along pre-established annular tracks (not shown). When one of the pallets is moved to the unloading area, the pallet wheels 100a are moved downwardly along the curved unloading rails (not shown), and under the action of the wheels 100a, the pallet is rotated around a rotating shaft 300, which can be a joint, fixed to the support beam, in order to allow the pallet's grid 3 plates to be tilted downwards to unload the material. Once the support beam portion bearing the material is the triangular beam 2 and the two side plates 22 of the triangular beam are provided, the mineral material on the left side plate 22 of the triangular beam positioned frontally (in relation to the direction of movement of the pallet) can slide downwardly along the downward sloping grid plates 3 of the pallet, and at the same time the mineral material on the right side plate 22 of the triangular beam positioned at the rear can slide downwardly along the downward sloping grid plates 3 previously mentioned, in order to be downloaded. When the next adjacent pallet is moved to the unloading area, the unloading process mentioned above will be repeated.

The second embodiment of the pallet support beam for the annular radiator according to the present invention differs from the first embodiment in that the through holes in the side plates 22 of the triangular beam are of rectangles parallel to each other. The rectangular through holes parallel to each other can be considered as three sets of through hole groups provided directly on the side plates 22 of the support beam's triangular beam (i.e., the frame includes three sets of through hole groups). Each set of through hole group includes a plurality of elongated rectangular through holes 22b parallel to or approximately parallel to each other, and each of the elongated rectangular through holes 22b may be of the same length.

The long sides of the rectangular through-holes 22b can be parallel to the

10/13 line connecting the annular radiator pallet 100 provided on the support beam and the center of the annular radiator, or they can be at a certain angle with respect to the connecting line.

To better guarantee the cooling effect of the mineral material, the long side of each elongated rectangular through hole 22b can be much longer than the short side of it, and the length of the short sides can be equal to the predetermined dimension of the grade plates 3 .------- The upper flange plate of the rectangular beam 1 of the annular radiator pallet support beam according to the second embodiment of the present invention is extended and extended towards both sides to form the plate lower 21 of the triangular beam, and portions of the upper flap plate of the rectangular beam 1 extending and expanding towards both sides are provided with air vents 21a. One portion of cooling air from the cooling air duct (not shown) flows in the layer of mineral material through the grid plates 3, while the other portion flows alongside the triangular beam 2 through the air vents 21 The. Since any of the two side plates 22 of the triangular beam, which are adjacent to the lower plate 21 of the triangular beam, is provided with three sets of through-hole group, and each through-hole group includes a plurality of elongated rectangular through holes 22b parallel to each other, the cooling air that went inside the triangular beam 2 can still enter the layer of mineral material above the support beam through these elongated rectangular through holes 22b parallel to or approximately parallel to each other in order to cool the mineral material, which effectively increases the ventilation area and thus improves the cooling effect for the mineral material above the support beam.

As the ventilation area of the side plates 22 of the triangular beam is increased, the amount of air per unit area is decreased and the average air speed is decreased. Since the resistance in the layer of mineral material is decreased in direct proportion to 1.67 of the airspeed power (ie, P = kv ^1.67 ). When the capacity of the cooling air duct to supply cooling air is constant (that is, the full pressure value is constant), the resistance in the annular radiator is decreased, while the amount of air supplied from the fans is correspondingly increased. The mineral material can be cooled better due to the increased amount of air.

As the cooling air passes through both the grid plates 3 and the side plates 22 of the triangular beams, the air velocity in the interior portion and on the surface of the mineral material layer becomes more uniform. Thus, fly ash is consequently decreased.

Naturally, the side plates 22 of the triangular beam according to the modality

11/13 of the present invention may also include two or more sets of through hole groups (i.e., the frame of any side plate 22 of the triangular beam includes two or more sets of through hole groups). Each set of the through hole group may also include elongated rectangular through holes 22b distributed equidistant or not equidistant, and the size of each elongated rectangular through hole 22b may be the same or different from each other.

To facilitate the manufacture of the side plates 22 of the triangular beam, a plurality of sub-plates can also be provided on the frames of the side plates 22 of the triangular beam, and be sequentially assembled to constitute the side plates 22 of the triangular beam with gaps or holes passing. That is, a plurality of sub-plates are installed sequentially on the side plate frames 22 of the triangular beam, so as to form the side plates 22 of the triangular beam with gaps or through holes. Subplates can be grid plate devices, or grid bar devices, or hole plate devices.

The grid plate of the grid plate device can be a bar-shaped steel plate, and parallel to the longitudinal direction of the pallet support beam, so as to effectively support mineral material having a larger size. Gaps in the grill plate on the grill plate device can act as air vents. The size of the grid plate gaps in the grid plate device can be determined conventionally according to the upper grid plates 3 of the annular radiator pallet, and is generally predetermined in the range of 8 ~ 12 mm.

The size of the grid plate device may correspond to that of the group of through holes (i.e., the frames) formed on the side plates 22 of the triangular beam, in order to facilitate disassembly, examination, repair and assembly.

The grid bars of the grid bar device can be round steel.

During assembly, the grid bars can be placed horizontally and parallel to the longitudinal direction of the pallet support beam. The gaps between the grid bars of the grid bar device can act as air vents. The size of the gaps between the grid bars can be equal to or slightly smaller than the gaps in the grid plate device mentioned earlier, and is generally predetermined in the 8 ~ 12 mm range.

The size of the grid bar device may correspond to that of the group of through holes (i.e., the frames) formed on the side plates 22 of the triangular beam, in order to facilitate disassembly, examination, repair and assembly.

The orifice plate device may be a steel plate formed with a plurality of small through-holes arranged densely. The small through-holes can be in the form of a circle, ellipse, rectangle and other polygons.

I

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Small through holes in the orifice plate device can act as air vents.

The size of the orifice plate device may correspond to that of the group of through-holes (i.e., the frames) on the side plates 22 of the triangular beam, in order to facilitate disassembly, examination, repair and assembly.

Since the side plates 22 of the triangular beam have grid plates, or grid bars, or plates with holes, or small gas passage holes 22b, which are all capable of ventilating air, it is possible to ensure that the cooling air in the triangular beam it can smoothly flow in the layer of mineral material in order to cool the mineral material.

Similarly, for the good cooling effect, the cross-sectional area of each air vent 21a is required to be greater than or equal to that of each rectangular through-hole 22b, and the total cross-sectional area is required of the air vents 21a is greater than that of the rectangular through-holes 22b.

The pallet support beam for the annular radiator according to this invention includes the rectangular beam 1 and the triangular beam 2 located on the rectangular beam 1. The upper flange plate of the rectangular beam 1 is extended and extended towards both sides. sides to form the lower plate 21 of the triangular beam, and the portions of the upper flange plate of the rectangular beam 1 extending and expanding towards both sides are provided with air vents 21 a. The cooling air enters the interior portion of the triangular beam 2 through the air vents 21a while entering the layer of mineral material through the grid plates 3. Since there is a plurality of through holes 22a (in the first embodiment) or rectangular through-holes 22b (in the second embodiment) provided on the two side plates 22 of the triangular beam adjacent to the lower plate of the triangular beam 2, the cooling air entering the triangular beam 2 can also enter the region B shown in Fig. 2 through of these through-holes 22a or rectangular through-holes 22b to cool the mineral material in region B, thereby improving the cooling effect for the mineral material above the support beam. The pallet support beam for the annular radiator according to the present invention can eliminate the dead cooling area, that is, region B. In addition, during the loading or cooling operation of the pallet, the loose material and the material powder falling on the inner triangular beam 5 can slide smoothly along the inclined surfaces of the inner triangular beam 5 on the lower flat plate of the pallet, which can prevent the mineral material from stacking on the upper flange plate of the rectangular beam 1 to increase the load of the annular radiator in operation, and also to protect the static sealing device and even that the pallet is damaged due to the spread of the stacked material when the pallet is repositioned after being unloaded.

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The foregoing descriptions are only preferred embodiments of the present invention and are not intended to limit the scope of protection of the present invention. Any modification, equivalent, improvement and the like made within the spirit and principle of the present invention should be considered to be within the scope of protection of the present invention defined by the claims.

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Claims (9)

1. Pallet support beam for an annular radiator to support the annular radiator pallet, which comprises a rectangular beam (1) and a triangular beam located on the rectangular beam (2), an upper flange plate of the rectangular beam ( 1) be extended and extended towards both sides to form a lower plate (21) of the triangular beam (2), portions of the upper flange plate of the rectangular beam (1) extending and expanding towards both sides to be provided with air vents (21a), and two side plates (22) of the triangular beam (2), which join the lower plate (21) of the triangular beam (2), are provided with a plurality of through holes (22a ); characterized by two solid plates (51, 52) connected on their sides being provided on the upper flange plate of the rectangular beam (1), and there is a certain distance between the connected sides of the two solid plates (51, 52) and the plate lower (21) of the triangular beam (2); and the angles between the two solid plates (51, 52) and the horizontal plane are greater than or equal to an angle of rest of the mineral material to be cooled by the pallets (100) of the annular radiator. 2. Pallet support beam for the annular radiator, according to claim 1, characterized in that the two solid plates (51, 52) are equal to the side plates (22) of the triangular beam (2) in length, and / or the angles between the two solid plates (51, 52) and the horizontal plane are the same or not the same, and / or the distances between the horizontal projections of the two solid plates (51, 52) and the air vents (21a) are pre-set to zero. 3. Pallet support beam for the annular radiator according to claim 1, characterized in that the shape and cross-sectional area of the through holes (22a) provided in the side plates (22) of the triangular beam (2) are determined according to an established size of the upper grid plates of the annular radiator pallet (100); and the through holes (22a) are triangular, or circular, or elliptical, or rectangular, or polygonal holes. 4. Pallet support beam for the annular radiator according to any one of claims 1 to 3, characterized in that the through holes (22a) have the same or different shapes. Petition 870170071266, of 9/22/2017, p. 8/9 2/2 5. Pallet support beam for the annular radiator according to claim 1, characterized in that any of the side plates (22) of the triangular beam (2) includes a frame and grid plate devices or grid bar devices or hole plate devices that are mounted on the frame and provided with a plurality of through holes (22a). 6. Pallet support beam for the annular radiator according to claim 5, characterized in that the through holes (22a) are triangular, or circular, or elliptical, or rectangular, or polygonal holes. 7. Pallet support beam for the annular radiator, according to claim 1, characterized in that the cross-sectional area of each air vent (21a) is greater than or equal to that of each through hole, and the area the total cross sections of the air vents (21a) be greater than the total area of the cross sections of the through holes (22a). 8. Pallet support beam for the annular radiator, according to claim 1, characterized in that the portion of the upper flange plate of the rectangular beam (1) extending and extending towards both sides is provided with at least one air ventilation (21a). 9. Pallet support beam for the annular radiator, according to claim 8, characterized in that the air vents (21a) provided in the portion of the upper flange plate of the rectangular beam (1) extending and expanding towards both the sides are independent of or in communication with each other, and the cross section of each air vent (21a) is circular, or elliptical, or triangular, or rectangular, or polygonal. Petition 870170071266, of 9/22/2017, p. 9/9 1/4