CN113566233A

CN113566233A - High-stability hook brick for power generation pot of garbage incinerator and use method

Info

Publication number: CN113566233A
Application number: CN202110783122.2A
Authority: CN
Inventors: 袁根芳
Original assignee: Yixing Zhongdian Wear And Fire Resistant Technology Co Ltd
Current assignee: Yixing Zhongdian Wear And Fire Resistant Technology Co Ltd
Priority date: 2021-07-12
Filing date: 2021-07-12
Publication date: 2021-10-29

Abstract

The invention discloses a high-stability retractor brick for a power generation pan of a garbage incinerator and a use method thereof, belonging to the technical field of retractor bricks, and the high-stability retractor brick for the power generation pan of the garbage incinerator comprises a lower brick body, wherein a lower groove is formed in the lower brick body, the high-stability retractor brick for the power generation pan of the garbage incinerator and the use method thereof are characterized in that after the top end of an inserted link is abutted against a first semicircle, the first semicircle is changed from an inclined state to a horizontal plane vertical to the ground, meanwhile, the first semicircle pulls a tension spring when the position is changed, when the first semicircle is positioned in an arc-shaped groove, the first semicircle is driven by the tension spring to rotate in the arc-shaped groove, and due to the movable connection between the second semicircle and the arc-shaped groove, the first semicircle drives a second semicircle to synchronously rotate in the arc-shaped groove after the tension spring rebounds, the first semicircle is clamped in the arc-shaped groove, thereby achieving the purpose of stably and firmly connecting the refractory brick with the hook brick.

Description

High-stability hook brick for power generation pot of garbage incinerator and use method

Technical Field

The invention relates to the technical field of drag hook bricks, in particular to a drag hook brick with high stability for a power generation pot of a garbage incinerator and a using method.

Background

In some industrial furnaces, need place the drag hook brick on resistant firebrick wall body, be used for placing the drag hook, traditional drag hook brick is that two bricks are constituteed, respectively have half hole from top to bottom, two bricks are put together and just are formed a complete hole, the hole is used for passing the drag hook, drag hook one end is fixed on the brick body, consequently, the drag hook brick receives the pulling force of drag hook, take place to remove easily, pull out the wall body, and because the drag hook is different at the pressure of exerting on two upper and lower bricks, relative movement also takes place easily between two bricks each other.

The existing device has the problem of low stability of the drag hook brick, so that the drag hook brick is poor in stability and poor in use effect and cannot meet the requirements of people, and therefore the drag hook brick for the power generation pot of the garbage incinerator and the use method are provided.

Disclosure of Invention

The invention aims to solve the problems that the stability of a drag hook brick is low, the stability of the drag hook brick is poor, the use effect is poor and the requirements of people cannot be met in the prior art, and provides the drag hook brick with high stability for a power generation pot of a garbage incinerator and a use method.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a garbage incinerator that stability is high drag hook brick for power generation pot, includes the brick body down, the lower recess has been seted up to the inside of the brick body down, and the top fixedly connected with lug of the brick body down, the reservation tank has been seted up to the inside of lug, and the top of the brick body is provided with the brick body down, go up the inside of the brick body and seted up first upper groove, and go up the brick body and keep away from one side of first upper groove and seted up the second upper groove, the inside of second upper groove is provided with strengthening mechanism, go up the top fixedly connected with connecting block of the brick body, and one side that the brick body was kept away from to the connecting block is provided with stable coupling mechanism, the below of first upper groove is provided with the drag hook, and one side swing joint of drag hook has stop gear.

Preferably, the external dimension of the bump is matched with the internal dimension of the second upper groove, and the upper brick body forms a clamping structure with the lower brick body through the bump.

Preferably, the reinforcing mechanism comprises a movable frame, an extrusion spring, insections, a first tooth post, a first shaft rod, a first clamping block, a second tooth post, a second shaft rod and a second clamping block, the movable frame is arranged inside the reinforcing mechanism, the outer wall of the movable frame is fixedly connected with the extrusion spring, the insections are arranged inside the movable frame, the movable frame is meshed with the first tooth post, the first shaft rod is fixedly connected inside the first tooth post, the first clamping block is fixedly connected to one side of the first tooth post, away from the first shaft rod, the second tooth post is movably connected to the bottom of the first tooth post, the second shaft rod is fixedly connected inside the second tooth post, and the second clamping block is fixedly connected to one side of the second tooth post, away from the second tooth post.

Preferably, the first tooth post rotates in the opposite direction between the movable frame and the second tooth post, the first clamping block forms a rotating structure between the first shaft rod and the first tooth post, and the first clamping block is connected with the inside of the reserved groove in a clamping mode.

Preferably, stabilize coupling mechanism and include inserted bar, arc wall, second semicircle, second pivot, first semicircle, first pivot, driving lever and extension spring, the top fixedly connected with inserted bar of connecting block, and the arc wall has been seted up to the inside of inserted bar, the inside sliding connection of arc wall has the second semicircle, and the inside swing joint of second semicircle has the second pivot, the top of inserted bar is provided with first semicircle, and the inside swing joint of first semicircle has first pivot, the outer wall fixedly connected with driving lever of first semicircle, and one side fixedly connected with extension spring that the outer wall of first semicircle is close to the driving lever.

Preferably, the second semicircle passes through to constitute revolution mechanic between second pivot and the inserted bar, and is identical between the outside dimension of second semicircle and the inside dimension of arc wall to the second semicircle is provided with two sets ofly.

Preferably, stop gear includes interior pole, thread bush, first pinion rack, gear, second movable rod, first movable rod, limiting plate and second pinion rack, stop gear's inside swing joint has interior pole, and the outer wall fixedly connected with thread bush of interior pole, the top meshing of thread bush is connected with first pinion rack, and the equal fixedly connected with rack in both sides of first pinion rack, one side meshing of rack is connected with the gear, and the top fixedly connected with second movable rod of gear, one side swing joint that the gear was kept away from to the second movable rod has first movable rod, and one side fixedly connected with limiting plate that the second movable rod was kept away from to first movable rod.

Preferably, the inner rod forms a meshing transmission structure with the first toothed plate through the threaded sleeve, the rack forms a meshing transmission structure with the gear through the first toothed plate, and the second movable rod forms a movable structure with the first movable rod through the gear.

Preferably, the first movable rods are distributed on the outer wall of the limiting plate at equal intervals, four groups of the first movable rods are arranged, and the second movable rods are symmetrical about the central axis of the limiting plate.

The scheme also provides a use method of the hook brick for the power generation pot of the garbage incinerator, which comprises the following steps:

s1, when using the device, firstly, the upper brick body is clamped and connected with the lower brick body through the convex block, the lower brick body is moved, the convex block at the top of the lower brick body is clamped and connected into the inside of the second upper groove, the first layer connection between the upper brick body and the lower brick body is completed through the clamping structure, simultaneously, the convex block at the top is driven to be clamped and connected into the inside of the second upper groove and simultaneously extrude the movable frame at one side when the lower brick body is moved, the movable frame is meshed with the first tooth post and the second tooth post inside through the tooth pattern when moving due to the tooth pattern arranged inside the movable frame, the first tooth post and the second tooth post are driven to rotate in opposite directions, the first tooth post and the first fixture block form a rotating structure through the first shaft lever, the second tooth post and the second fixture block form a rotating structure through the second shaft lever, and the first fixture block and the second fixture block are driven to be clamped and connected in the reserved groove, the reinforced connection between the upper brick body and the lower brick body is completed;

s2, connecting the whole drag hook brick with a refractory brick to prevent the drag hook brick from moving when in use, firstly inserting the inserted link into the stable connection mechanism, and extruding the first semicircle after the top end of the inserted link is abutted against the first semicircle in the insertion process to enable the first semicircle to be changed from an inclined state to a horizontal plane perpendicular to the ground;

s3, then, the first semicircle pulls the extension spring when the position is changed, when the first semicircle is positioned in the arc-shaped groove, the first semicircle is driven by the extension spring to rotate in the arc-shaped groove, and due to the movable connection between the second semicircle and the arc-shaped groove, the first semicircle drives the second semicircle to synchronously rotate in the arc-shaped groove after the resilience of the extension spring is pulled, so that the first semicircle is clamped in the arc-shaped groove, the purpose of stably and firmly connecting the refractory brick and the hook brick is achieved, and when the stable connection structure is required to be disassembled, the first semicircle is driven to rotate by pulling the deflector rod, so that the first semicircle is not limited in the arc-shaped groove;

s4, then, placing a draw hook in a through hole formed between the first upper groove and the lower groove, and when the draw hook penetrates through the through hole and pulls a draw hook brick, avoiding the problem that the draw hook does not fall out of the through hole, so that after the draw hook penetrates through the through hole, rotating an inner rod in the draw hook, wherein the outer wall of the inner rod is fixedly connected with a threaded sleeve;

s5, finally, the rack meshes between the gear of removal in-process and one side, it rotates to drive the gear, because the top fixedly connected with second movable rod of gear, therefore gear revolve, it removes to drive the second movable rod, the first movable rod of second movable rod removal pulling moves about, when gear revolve drives first movable rod and second movable rod and is close to through-hole department, the length of first movable rod and second movable rod is greater than the radius size of through-hole, restrict the drag hook outside the through-hole, avoid the condition that the drag hook drops to appear in the use.

Compared with the prior art, the invention provides the hook brick for the power generation pot of the garbage incinerator, which has the following beneficial effects:

1. according to the high-stability retractor brick for the power generation pot of the garbage incinerator, the first clamping block and the second clamping block are arranged, in the reinforcing mechanism, when the lower brick body moves, the lower brick body drives the lug at the top to be clamped into the second upper groove and simultaneously extrude the movable frame on one side, and the movable frame is internally provided with the insections, so that the movable frame is meshed with the first tooth post and the second tooth post inside through the insections during moving, the first tooth post and the second tooth post are driven to rotate in opposite directions, the first tooth post and the first clamping block form a rotating structure through the insections, the second tooth post and the second clamping block form a rotating structure through the second shaft rod, the first clamping block and the second clamping block are driven to be clamped in the reserved groove, and the reinforcing connection between the upper brick body and the lower brick body is completed;

2. this high garbage incinerator drag hook brick for power pot of stability, through setting up first semicircle and second semicircle, in stable coupling mechanism, the inserted bar inserts stable coupling mechanism's inside, the top of inserted bar is supported after touching first semicircle, make first semicircle transform to horizontal plane perpendicular to ground by the tilt state, first semicircle pulls extension spring when taking place the position transform simultaneously, when first semicircle is located the inside of arc wall, first semicircle is driven by extension spring, rotate in the inside of arc wall, because swing joint between second semicircle and the arc wall, first semicircle drives the second semicircle and rotates in the arc wall inside synchronously after pulling the resilience of extension spring, block first semicircle in the inside of arc wall, thereby reach the purpose of carrying out stable firm connection with the drag hook brick to resistant firebrick;

3. the high-stability drag hook brick for the power generation pot of the garbage incinerator is characterized in that a first movable rod and a second movable rod are arranged, in a limiting mechanism, after the drag hook penetrates through the inside of a through hole, an inner rod inside the drag hook is rotated, a threaded sleeve is fixedly connected to the outer wall of the inner rod, when the inner rod is rotated, the threaded sleeve synchronously rotates to drive a first toothed plate and a second toothed plate to move in position, the first toothed plate and the second toothed plate drive a rack to move when moving, the rack is meshed with a gear on one side in the moving process to drive the gear to rotate, a second movable rod is fixedly connected to the top of the gear, the gear rotates to drive the second movable rod to move, the second movable rod moves to pull the first movable rod to move, when the first movable rod and the second movable rod are driven to be close to the through hole through the gear rotation, the lengths of the first movable rod and the second movable rod are larger than the radius size of the through hole, the draw hook is limited outside the through hole, so that the situation that the draw hook falls off in the use process is avoided;

4. this high garbage incinerator is drag hook brick for power generation pot of stability through setting up the lug, at the top of the brick body down, goes up the brick body and carries out the block through the lug and be connected down between the brick body, removes the brick body down, goes into the inside of second upper groove through the lug block at brick body top down, through the block structure, accomplishes to go up the brick body and be connected with the first layer between the brick body down.

Drawings

Fig. 1 is a schematic view of an overall external first visual angle structure of the high-stability retractor brick for the power generation pot of the garbage incinerator.

Fig. 2 is a schematic view of an overall external second visual angle structure of the high-stability retractor brick for the power generation pot of the garbage incinerator.

Fig. 3 is a schematic view of an overall external third visual angle structure of the high-stability retractor brick for the power generation pot of the garbage incinerator.

Fig. 4 is a schematic view of a first visual angle structure inside the reinforcing mechanism of the high-stability hook brick for the power generation pot of the garbage incinerator.

Fig. 5 is a schematic view of a second visual angle structure inside the reinforcing mechanism of the high-stability hook brick for the power generation pot of the garbage incinerator.

Fig. 6 is a schematic view of a detachable structure inside the limiting mechanism of the high-stability hook brick for the power generation pot of the garbage incinerator.

Fig. 7 is a schematic view of the internal cross-sectional structure of the limiting mechanism of the high-stability hook brick for the power generation pot of the garbage incinerator.

Fig. 8 is a schematic view of the internal cross-sectional structure of the stable connecting mechanism of the hook brick for the power generation pot of the garbage incinerator with high stability.

In the figure: 1. a brick body is arranged; 2. a lower groove; 3. a bump; 4. reserving a groove; 5. putting a brick body; 6. a first upper groove; 7. a reinforcement mechanism; 701. a movable frame; 702. a compression spring; 703. insection; 704. a first tooth post; 705. a first shaft lever; 706. a first clamping block; 707. a second tooth post; 708. a second shaft lever; 709. a second fixture block; 8. connecting blocks; 9. a stable connection mechanism; 901. inserting a rod; 902. an arc-shaped slot; 903. a second semicircle; 904. a second rotating shaft; 905. a first semicircle; 906. a first rotating shaft; 907. a deflector rod; 908. an extension spring; 10. pulling a hook; 11. a limiting mechanism; 1101. an inner rod; 1102. a threaded sleeve; 1103. a first toothed plate; 1104. a rack; 1105. a gear; 1106. a second movable bar; 1107. a first movable bar; 1108. a limiting plate; 1109. a second toothed plate; 12. a second upper groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-8, a high-stability retractor brick for a power generation pot of a garbage incinerator, including lower brick body 1, lower groove 2 has been seted up to the inside of lower brick body 1, and lower brick body 1's top fixedly connected with lug 3, reserve tank 4 has been seted up to the inside of lug 3, and lower brick body 1's top is provided with brick body 5, first upper groove 6 has been seted up to the inside of going up brick body 5, and go up brick body 5 and keep away from one side of first upper groove 6 and seted up second upper groove 12, the inside of second upper groove 12 is provided with reinforcing mechanism 7, go up brick body 5's top fixedly connected with connecting block 8, and connecting block 8 keeps away from one side of last brick body 5 and is provided with stable coupling mechanism 9, the below of first upper groove 6 is provided with retractor 10, and one side swing joint of retractor 10 has stop gear 11.

Furthermore, the external size of the convex block 3 is matched with the internal size of the second upper groove 12, the upper brick body 5 forms a clamping structure with the lower brick body 1 through the convex block 3, and the upper brick body 5 forms a clamping structure with the lower brick body 1 through the convex block 3, so that the upper brick body 5 and the lower brick body 1 can be connected, and the influence on the use stability of the device caused by position movement in the use process is avoided;

further, the reinforcing mechanism 7 comprises a movable frame 701, an extrusion spring 702, insections 703, a first tooth post 704, a first shaft rod 705, a first fixture block 706, a second tooth post 707, a second shaft rod 708 and a second fixture block 709, the movable frame 701 is arranged inside the reinforcing mechanism 7, the extrusion spring 702 is fixedly connected to the outer wall of the movable frame 701, the insections 703 are arranged inside the movable frame 701, the first tooth post 704 is engaged and connected to the inside of the movable frame 701, the first shaft rod 705 is fixedly connected to the inside of the first tooth post 704, the first fixture block 706 is fixedly connected to one side of the first shaft rod 705 away from the first tooth post 704, the second tooth post 707 is movably connected to the bottom of the first tooth post 704, the second shaft rod 708 is fixedly connected to the inside of the second tooth post 707, the second fixture block 709 is fixedly connected to one side of the second shaft rod 708 away from the second tooth post 707, and the firmness of the connection between the upper brick body 5 and the lower brick body 1 can be increased by using the reinforcing mechanism 7, so as to prevent the upper brick body 5 and the lower brick body 1 from being dislocated when the drag hook 10 pulls the drag hook brick, thereby influencing the normal use of the drag hook brick;

further, the first tooth post 704 rotates in the opposite direction between the movable frame 701 and the second tooth post 707 through the first shaft rod 705, the first fixture block 706 forms a rotating structure with the first tooth post 704 through the first shaft rod 705, and the first fixture block 706 is connected with the inside of the reserved groove 4 in a clamping manner through the projection 3 while being inserted into the second upper groove 12, the projection 3 pushes the movable frame 701 to slide in the first upper groove 6, the insections 703 in the movable frame 701 are respectively meshed with the first tooth post 704 and the second tooth post 707 in the sliding process, so that the first tooth post 704 and the second tooth post 707 are driven to rotate in the opposite direction, the first fixture block 706 and the second fixture block 709 are driven to be synchronously clamped in the reserved groove 4, and the purpose of increasing the firmness of the connection between the upper brick body 5 and the lower brick body 1 is achieved;

further, the stable connection mechanism 9 comprises an insertion rod 901, an arc-shaped slot 902, a second semicircle 903, a second rotating shaft 904, a first semicircle 905, a first rotating shaft 906, a shifting rod 907 and an extension spring 908, the insertion rod 901 is fixedly connected to the top of the connection block 8, an arc-shaped groove 902 is arranged inside the inserting rod 901, a second semicircle 903 is connected inside the arc-shaped groove 902 in a sliding way, a second rotating shaft 904 is movably connected inside the second semicircle 903, a first semicircle 905 is arranged above the inserted link 901, a first rotating shaft 906 is movably connected inside the first semicircle 905, a driving lever 907 is fixedly connected on the outer wall of the first semicircle 905, the side, close to the deflector rod 907, of the outer wall of the first semicircle 905 is fixedly connected with the extension spring 908, and the stable connection mechanism 9 is utilized, so that the hook bricks can be conveniently connected with refractory bricks, the unstable situation of the hook bricks in the use process is avoided, and the hook bricks are prevented from moving;

further, a rotating structure is formed between the second semicircle 903 and the inserting rod 901 through the second rotating shaft 904, the external size of the second semicircle 903 is matched with the internal size of the arc-shaped groove 902, two groups of second semicircles 903 are arranged, and the rotating structure is formed between the second rotating shaft 904 and the inserting rod 901 through the second semicircle 903, so that the second semicircle 903 can form a complete circle with the first semicircle 905 after contacting the first semicircle 905 and can rotate in the arc-shaped groove 902 to clamp and limit the first semicircle 905 in the arc-shaped groove 902;

further, the limiting mechanism 11 comprises an inner rod 1101, a threaded sleeve 1102, a first toothed plate 1103, a rack 1104, a gear 1105, a second movable rod 1106, a first movable rod 1107, a limiting plate 1108 and a second toothed plate 1109, the inner rod 1101 is movably connected inside the limiting mechanism 11, the threaded sleeve 1102 is fixedly connected to the outer wall of the inner rod 1101, the first toothed plate 1103 is connected to the top of the threaded sleeve 1102 in a meshing manner, the rack 1104 is fixedly connected to both sides of the first toothed plate 1103, the gear 1105 is connected to one side of the rack 1104 in a meshing manner, the second movable rod 1106 is fixedly connected to the top of the gear 1105, the first movable rod 1107 is movably connected to one side of the second movable rod 1106 away from the gear 1105, the limiting plate is fixedly connected to one side of the first movable rod 1107 away from the second movable rod 1106, and the position of the draw hook 10 can be limited when the draw hook 1108 runs through between the first upper groove 6 and the lower groove 2 by using the limiting mechanism 11, the inconvenience caused by the fact that the L-shaped draw hook is used when the L-shaped draw hook is introduced into the through hole is avoided, and the situation that the draw hook falls off when the draw hook is used for pulling the draw hook brick is avoided by using the limiting mechanism 11;

further, the inner rod 1101 forms a meshing transmission structure with the first toothed plate 1103 through the threaded sleeve 1102, the rack 1104 forms a meshing transmission structure with the gear 1105 through the first toothed plate 1103, the second movable rod 1106 forms a movable structure with the first movable rod 1107 through the gear 1105, and the second movable rod 1106 forms a movable structure with the first movable rod 1107 through the gear 1105, so that when the first movable rod 1107 is movably pulled close to the top end of the position-limiting plate 1108 close to the drag hook 10, the first movable rod 1107 and the second movable rod 1106 are clamped outside the through hole formed by the lower groove 2 of the first upper groove 6, the drag hook 10 is limited inside the through hole, and the situation that the drag hook 10 falls off in the pulling use process is avoided;

further, the first movable rods 1107 are equidistantly distributed on the outer wall of the limiting plate 1108, four groups of the first movable rods 1107 are arranged, the second movable rods 1106 are symmetrical about the central axis of the limiting plate 1108, and the pull hook 10 can be better limited for children outside the through hole by using the groups of the first movable rods 1107 and the second movable rods 1106 which are equidistantly distributed, so that inconvenience of the pull hook 10 in the use process is avoided;

the embodiment also provides a high garbage incinerator power generation pot drag hook brick's of stability use scheme, adopts above device, includes following steps:

s1, when the device is used, firstly, the upper brick body 5 is clamped and connected with the lower brick body 1 through the convex block 3, the lower brick body 1 is moved, the convex block 3 at the top of the lower brick body 1 is clamped and connected into the inside of the second upper groove 12, the first layer connection between the upper brick body 5 and the lower brick body 1 is completed through the clamping structure, meanwhile, when the lower brick body 1 moves, the convex block 3 at the top is driven to be clamped and connected into the inside of the second upper groove 12 and simultaneously extrude the movable frame 701 at one side, because the inside of the movable frame 701 is provided with the insection 703, the movable frame 701 is meshed with the first insection 704 and the second insection 707 inside through the insection 703 during moving, the first insection 704 and the second insection 707 are driven to rotate in opposite directions, because the first insection 704 forms a rotating structure with the first fixture block 706 through the first shaft rod 705, and the second insection 707 forms a rotating structure with the second fixture 709, therefore, the first fixture block 706 and the second fixture block 709 are driven to be clamped in the reserved groove 4, and the reinforced connection between the upper brick body 5 and the lower brick body 1 is completed;

s2, connecting the whole drag hook brick with a refractory brick to prevent the drag hook brick from moving when in use, firstly inserting the inserting rod 901 into the stable connecting mechanism 9, and extruding the first semicircle 905 after the top end of the inserting rod 901 abuts against the first semicircle 905 in the inserting process to ensure that the first semicircle 905 is changed from an inclined state to a horizontal plane vertical to the ground;

s3, then, the first semicircle 905 pulls the extension spring 908 when the position is changed, when the first semicircle 905 is located inside the arc-shaped slot 902, the first semicircle 905 is driven by the extension spring 908 and rotates inside the arc-shaped slot 902, and because the second semicircle 903 is movably connected with the arc-shaped slot 902, the first semicircle 905 drives the second semicircle 903 to synchronously rotate inside the arc-shaped slot 902 after the tension spring 908 rebounds, and the first semicircle 905 is clamped inside the arc-shaped slot 902, so that the purpose of stably and firmly connecting the refractory brick and the hook brick is achieved, if the stable connection structure needs to be disassembled, the first semicircle 905 is driven to rotate by pulling the deflector rod 907, and the first semicircle 905 is not limited inside the arc-shaped slot 902;

s4, then, placing the draw hook 10 in a through hole formed between the first upper groove 6 and the lower groove 2, and when the draw hook 10 penetrates through the through hole, and pulling a draw hook brick, the problem that the draw hook 10 does not fall out of the through hole is avoided, so that after the draw hook 10 penetrates through the through hole, rotating an inner rod 1101 in the draw hook 10, wherein a threaded sleeve 1102 is fixedly connected to the outer wall of the inner rod 1101, and when the inner rod 1101 rotates, the threaded sleeve 1102 synchronously rotates to drive a first toothed plate 1103 and a second toothed plate 1109 to move in position, and the first toothed plate 1103 and the second toothed plate 1109 drive a rack 1104 to move when moving;

s5, finally, the rack 1104 is meshed with the gear 1105 on one side in the moving process, the gear 1105 is driven to rotate, the second movable rod 1106 is fixedly connected to the top of the gear 1105, the gear 1105 rotates, the second movable rod 1106 is driven to move, the second movable rod 1106 moves to pull the first movable rod 1107 to move, when the gear 1105 rotates to drive the first movable rod 1107 and the second movable rod 1106 to be close to the through hole, the lengths of the first movable rod 1107 and the second movable rod 1106 are larger than the radius of the through hole, the drag hook 10 is limited outside the through hole, and the condition that the drag hook 10 falls off in the using process is avoided.

When the device is used, firstly, the upper brick body 5 is clamped and connected with the lower brick body 1 through the convex block 3, the lower brick body 1 is moved, the convex block 3 at the top of the lower brick body 1 is clamped and connected into the inner part of the second upper groove 12, the first layer connection between the upper brick body 5 and the lower brick body 1 is completed through the clamping structure, meanwhile, the lower brick body 1 drives the convex block 3 at the top to be clamped and connected into the inner part of the second upper groove 12 and simultaneously extrudes the movable frame 701 at one side, because the inner part of the movable frame 701 is provided with the insection 703, the movable frame 701 is meshed with the first insection 704 and the second insection 707 in the inner part through the insection 703 during moving, the first insection 704 and the second insection 707 are driven to rotate in opposite directions, because the first insection 704 forms a rotating structure with the first fixture block 706 through the first shaft rod 705, and the second insection 707 forms a rotating structure with the second fixture block 709 through the second shaft rod 708, therefore, the first fixture block 706 and the second fixture block 709 are driven to be clamped in the reserved groove 4, and the reinforced connection between the upper brick body 5 and the lower brick body 1 is completed;

then, the whole drag hook brick is connected with a refractory brick, so that the drag hook brick is prevented from moving when in use, the inserting rod 901 is firstly inserted into the stable connecting mechanism 9, and in the inserting process, after the top end of the inserting rod 901 abuts against the first semicircle 905, the first semicircle 905 is extruded, so that the first semicircle 905 is changed from an inclined state to a horizontal plane vertical to the ground;

then, the first semicircle 905 pulls the extension spring 908 when the position of the first semicircle is changed, when the first semicircle 905 is located inside the arc-shaped slot 902, the first semicircle 905 is driven by the extension spring 908 and rotates inside the arc-shaped slot 902, and the second semicircle 903 is movably connected with the arc-shaped slot 902, so that the first semicircle 905 drives the second semicircle 903 to synchronously rotate inside the arc-shaped slot 902 after the tension spring 908 rebounds, and the first semicircle 905 is clamped inside the arc-shaped slot 902, so that the purpose of stably and firmly connecting the refractory brick and the hook brick is achieved, if the stable connection structure needs to be disassembled, the first semicircle 905 is driven to rotate by pulling the poking rod 907, and the first semicircle 905 is not limited inside the arc-shaped slot 902;

then, the draw hook 10 is arranged in a through hole formed between the first upper groove 6 and the lower groove 2, when the draw hook 10 penetrates through the through hole and a draw hook brick is pulled, the problem that the draw hook 10 does not fall out of the through hole is avoided, therefore, after the draw hook 10 penetrates through the through hole, the inner rod 1101 in the draw hook 10 is rotated, the outer wall of the inner rod 1101 is fixedly connected with a threaded sleeve 1102, when the inner rod 1101 is rotated, the threaded sleeve 1102 synchronously rotates to drive the first toothed plate 1103 and the second toothed plate 1109 to move in position, and the first toothed plate 1103 and the second toothed plate 1109 drive the rack 1104 to move when moving;

finally, the rack 1104 is engaged with the gear 1105 on one side in the moving process, the gear 1105 is driven to rotate, the second movable rod 1106 is fixedly connected to the top of the gear 1105, the gear 1105 rotates, the second movable rod 1106 is driven to move, the second movable rod 1106 moves to pull the first movable rod 1107 to move, when the gear 1105 rotates to drive the first movable rod 1107 and the second movable rod 1106 to be close to the through hole, the lengths of the first movable rod 1107 and the second movable rod 1106 are larger than the radius of the through hole, the drag hook 10 is limited outside the through hole, and the condition that the drag hook 10 falls off in the using process is avoided.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims

1. The utility model provides a high garbage incinerator is drag hook brick for power generation pot of stability, includes brick body (1) down, its characterized in that: a lower groove (2) is arranged inside the lower brick body (1), a convex block (3) is fixedly connected with the top of the lower brick body (1), a reserved groove (4) is arranged inside the convex block (3), an upper brick body (5) is arranged above the lower brick body (1), a first upper groove (6) is arranged inside the upper brick body (5), and one side of the upper brick body (5) far away from the first upper groove (6) is provided with a second upper groove (12), a reinforcing mechanism (7) is arranged inside the second upper groove (12), the top of the upper brick body (5) is fixedly connected with a connecting block (8), and one side of the connecting block (8) far away from the upper brick body (5) is provided with a stable connecting mechanism (9), a draw hook (10) is arranged below the first upper groove (6), and one side of the draw hook (10) is movably connected with a limiting mechanism (11).

2. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 1, characterized in that: the external dimension of the convex block (3) is matched with the internal dimension of the second upper groove (12), and the upper brick body (5) forms a clamping structure with the lower brick body (1) through the convex block (3).

3. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 1, characterized in that: the reinforcing mechanism (7) comprises a movable frame (701), an extrusion spring (702), insections (703), a first tooth post (704), a first shaft rod (705), a first fixture block (706), a second tooth post (707), a second shaft rod (708) and a second fixture block (709), the movable frame (701) is arranged inside the reinforcing mechanism (7), the extrusion spring (702) is fixedly connected to the outer wall of the movable frame (701), the insections (703) are arranged inside the movable frame (701), the first tooth post (704) is meshed and connected inside the movable frame (701), the first shaft rod (705) is fixedly connected inside the first tooth post (704), the first fixture block (706) is fixedly connected to one side, far away from the first tooth post (704), of the first shaft rod (705), the second tooth post (707) is movably connected to the bottom of the first tooth post (704), and the second fixture block (708) is fixedly connected inside the second tooth post (707), a second clamping block (709) is fixedly connected to one side, far away from the second tooth column (707), of the second shaft lever (708).

4. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 3, characterized in that: the first tooth column (704) rotates in the opposite direction through the movable frame (701) and the second tooth column (707), the first clamping block (706) forms a rotating structure through the first shaft rod (705) and the first tooth column (704), and the first clamping block (706) is connected with the inside of the reserved groove (4) in a clamping mode.

5. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 1, characterized in that: the stable connecting mechanism (9) comprises an inserting rod (901), an arc-shaped groove (902), a second semicircle (903), a second rotating shaft (904), a first semicircle (905), a first rotating shaft (906), a shifting rod (907) and an extension spring (908), the inserting rod (901) is fixedly connected to the top of the connecting block (8), an arc-shaped groove (902) is formed in the inserting rod (901), a second semicircle (903) is connected in the arc-shaped groove (902) in a sliding manner, a second rotating shaft (904) is movably connected inside the second semicircle (903), a first semicircle (905) is arranged above the inserted link (901), a first rotating shaft (906) is movably connected inside the first semicircle (905), a deflector rod (907) is fixedly connected on the outer wall of the first semicircle (905), and one side of the outer wall of the first semicircle (905) close to the deflector rod (907) is fixedly connected with an extension spring (908).

6. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 5, characterized in that: the second semicircle (903) and the inserted bar (901) form a rotating structure through a second rotating shaft (904), the external size of the second semicircle (903) is matched with the internal size of the arc-shaped groove (902), and two groups of the second semicircles (903) are arranged.

7. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 1, characterized in that: the limiting mechanism (11) comprises an inner rod (1101), a threaded sleeve (1102), a first toothed plate (1103), a rack (1104), a gear (1105), a second movable rod (1106), a first movable rod (1107), a limiting plate (1108) and a second toothed plate (1109), the inner rod (1101) is movably connected inside the limiting mechanism (11), and the outer wall of the inner rod (1101) is fixedly connected with a threaded sleeve (1102), the top of the threaded sleeve (1102) is engaged and connected with a first toothed plate (1103), and both sides of the first toothed plate (1103) are fixedly connected with racks (1104), one side of each rack (1104) is connected with a gear (1105) in a meshing way, the top of the gear (1105) is fixedly connected with a second movable rod (1106), one side of the second movable rod (1106) far away from the gear (1105) is movably connected with a first movable rod (1107), and a limiting plate (1108) is fixedly connected to one side of the first movable rod (1107) far away from the second movable rod (1106).

8. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 7, characterized in that: the inner rod (1101) forms a meshing transmission structure between the threaded sleeve (1102) and the first toothed plate (1103), the rack (1104) forms a meshing transmission structure between the first toothed plate (1103) and the gear (1105), and the second movable rod (1106) forms a movable structure between the gear (1105) and the first movable rod (1107).

9. The high-stability retractor brick for the power generation pot of the garbage incinerator according to claim 7, characterized in that: the first movable rods (1107) are distributed on the outer wall of the limiting plate (1108) at equal intervals, four groups of the first movable rods (1107) are arranged, and the second movable rods (1106) are symmetrical about the central axis of the limiting plate (1108).

10. A use method of the hook brick for the power generation pot of the garbage incinerator with high stability is characterized by comprising the following steps:

s1, when the device is used, firstly, the upper brick body (5) is clamped and connected with the lower brick body (1) through the convex block (3), the lower brick body (1) is moved, the convex block (3) at the top of the lower brick body (1) is clamped and connected into the inner part of the second upper groove (12), the connection of the first layer between the upper brick body (5) and the lower brick body (1) is completed through the clamping structure, meanwhile, the lower brick body (1) drives the convex block (3) at the top to be clamped and connected into the inner part of the second upper groove (12) and simultaneously extrude the movable frame (701) at one side when moving, because the inner part of the movable frame (701) is provided with the insection (703), the movable frame (701) is meshed with the first insection column (704) and the second insection column (707) inside when moving, the movable frame (701) is driven to rotate in the opposite direction between the first insection column (704) and the second insection column (707), the first tooth column (704) forms a rotating structure with the first clamping block (706) through the first shaft rod (705), and the second tooth column (707) forms a rotating structure with the second clamping block (709) through the second shaft rod (708), so that the first clamping block (706) and the second clamping block (709) are driven to be clamped in the reserved groove (4), and the reinforced connection between the upper brick body (5) and the lower brick body (1) is completed;

s2, then, the whole drag hook brick is connected with a refractory brick, the drag hook brick is prevented from moving when in use, an inserted link (901) is inserted into a stable connection mechanism (9), and in the insertion process, after the top end of the inserted link (901) is abutted against a first semicircle (905), the first semicircle (905) is extruded, so that the first semicircle (905) is changed from an inclined state to a horizontal plane vertical to the ground;

s3, then, the first semicircle (905) pulls the extension spring (908) when the position change occurs, when the first semicircle (905) is positioned in the arc-shaped groove (902), the first semicircle (905) is driven by the tension spring (908), rotates in the arc-shaped groove (902), and because the second semicircle (903) is movably connected with the arc-shaped groove (902), therefore, the first semicircle (905) drives the second semicircle (903) to synchronously rotate in the arc-shaped groove (902) after the tension spring (908) rebounds, the first semicircle (905) is clamped in the arc-shaped groove (902), thereby achieving the purpose of stably and firmly connecting the refractory brick and the drag hook brick, when the stable connecting structure is needed to be disassembled, the first semicircle (905) is driven to rotate by pulling the poking rod (907), so that the first semicircle (905) is not limited in the arc-shaped groove (902);

s4, then, the draw hook (10) is placed inside a through hole formed between the first upper groove (6) and the lower groove (2), when the draw hook (10) penetrates through the inside of the through hole and pulls a hook brick, the problem that the draw hook (10) does not fall off from the inside of the through hole is avoided, therefore, after the draw hook (10) penetrates through the inside of the through hole, the inner rod (1101) inside the draw hook (10) is rotated, the outer wall of the inner rod (1101) is fixedly connected with the threaded sleeve (1102), when the inner rod (1101) is rotated, the threaded sleeve (1102) synchronously rotates to drive the first toothed plate (1103) and the second toothed plate (1109) to move in position, and the first toothed plate (1103) and the second toothed plate (1109) drive the toothed plate (1104) to move when moving;

s5, finally, the rack (1104) is meshed with the gear (1105) on one side in the moving process, the gear (1105) is driven to rotate, the second movable rod (1106) is fixedly connected to the top of the gear (1105), so the gear (1105) rotates to drive the second movable rod (1106) to move, the second movable rod (1106) moves to pull the first movable rod (1107) to move, when the gear (1105) rotates to drive the first movable rod (1107) and the second movable rod (1106) to be close to the through hole, the lengths of the first movable rod (1107) and the second movable rod (1106) are larger than the radius of the through hole, the drag hook (10) is limited outside the through hole, and the falling-off condition of the drag hook (10) in the using process is avoided.