Seaside green building planting structure

Abstract

The application discloses a kind of green building planting structures of coastal area, it is related to green building planting structures of coastal area technical field, the green building planting structure of coastal area, the inside of roof panel is provided with greenery pot, the top of roof panel is provided with through-hole, the protection device for protecting the green plant in greenery pot is arranged on roof panel, and the firm device for preventing green plant from separating from soil is arranged on greenery pot;Among them, the protection device includes motor, threaded rod, placement plate, inclined surface block, extrusion block, bending block, connecting spring, extrusion column, inclined chute, control panel and baffle;The green building planting structure of coastal area, when in coastal area is used, when encountering heavy rain or gale, by starting motor, placement plate can be driven to move downwards, so that greenery pot is extended into roof panel, so as to be able to play the protection to green plant in greenery pot, solve the problem that green plant is damaged under the influence of gale or heavy rain.

Description

Technical Field

[0001] This invention relates to the field of green building planting structure technology, specifically a green building planting structure for coastal areas. Background Technology

[0002] Currently, green building refers to architecture that is environmentally friendly, makes full use of natural resources, and is constructed without disrupting the basic ecological balance of the environment. It represents a shared benefit between humanity and nature, and between the present and the future, and is a means of sustainable development. "Coastal green building planting structure" refers to a composite planting system that combines ecological, energy-saving, and aesthetic functions in coastal environments characterized by high salt spray, strong winds, and high humidity. This system utilizes salt- and wind-tolerant plants and supporting structural systems on building roofs, terraces, sky gardens, or facades.

[0003] Existing green building planting structures along the coast are prone to damage due to frequent storms and heavy rains. These storms and rains can easily wash away or blow away the plants and soil, causing significant damage to the plants. Therefore, a new green building planting structure for coastal areas is proposed. Summary of the Invention

[0004] To address the shortcomings of existing technologies, this invention provides a green building planting structure for coastal areas, which solves the problems mentioned in the background section.

[0005] To achieve the above objectives, the present invention is implemented through the following technical solution: a green building planting structure for coastal areas, including a roof panel, a greening pot is provided inside the roof panel, a through hole is provided on the top of the roof panel, a protective device is provided on the roof panel to protect the green plants in the greening pot, and a stabilizing device is provided on the greening pot to prevent the green plants from detaching from the soil.

[0006] The protective device includes a motor, a threaded rod, a placement plate, an inclined block, an extrusion block, a bending block, a connecting spring, an extrusion column, a sloping groove, a control panel, and a baffle. The motor is fixed to the inner wall of the roof panel, the threaded rod is fixed to the top output end of the motor, the placement plate is threaded to the outer wall of the threaded rod, the placement plate is slidably installed on the inner wall of the roof panel, the greening basin is detachably installed on the top of the placement plate, the inclined block penetrates the side wall of the roof panel and is slidably connected at the penetration point, and the extrusion block is fixed to the top of the placement plate. When the motor is started, it can drive the placement plate to move upward, thereby allowing the greening basin to be removed from the through hole at the top of the roof panel.

[0007] According to the above technical solution, the bending block is fixed to the side wall of the inclined block, one side of the connecting spring is fixed to the side wall of the roof panel, and the other side of the connecting spring is fixed to the side wall of the bending block.

[0008] According to the above technical solution, the baffle is slidably installed on the top of the roof panel, and the baffle has an inclined groove. The extrusion column is fixed to the bottom outer wall of the bending block, and the outer wall of the extrusion column is in contact with the inner wall of the inclined groove. The control panel is fixed to the side wall of the roof panel and is electrically connected to the motor. When the placement plate moves upward, the extrusion block will press against the inclined surface of the inclined block, causing the inclined block to move out of the side wall of the roof panel under the extrusion force. This will drive the bending block to move, and the extrusion column will move in the inclined groove, thereby pressing the two sets of baffles away from each other.

[0009] According to the above technical solution, the stabilizing device includes a transmission block, a compaction plate, a transmission spring, an L-shaped block, a fixing block, a push block, a long plate, an insert block, a return spring, a slide groove, and a slide rod. The transmission block passes through the side wall of the greening pot and is slidably connected at the penetration point. The compaction plate is fixed to the side wall of the transmission block. One side of the transmission spring is fixed to the side wall of the compaction plate, and the other side of the transmission spring is fixed to the inner side of the greening pot. The L-shaped block passes through the top of the compaction plate and is slidably connected at the penetration point. When the placement plate moves the greening pot upwards and the inclined surface of the transmission block presses against the inner wall of the through hole, the transmission block will be subjected to compressive force, which can drive the transmission block to move into the greening pot and drive the compaction plate to compress the soil in the greening pot.

[0010] According to the above technical solution, the push block is fixed to the outer wall of the L-shaped block, the fixing block is fixed to the top of the side wall of the greening pot, the long plate is fixed to the bottom of the L-shaped block, the insert block passes through the side wall of the compaction plate and is slidably connected at the penetration point, and the sliding groove is opened on the insert block.

[0011] According to the above technical solution, the top of the reset spring is fixed to the bottom of the long plate, the bottom of the reset spring is fixed to the inner wall of the compaction plate, the sliding rod is fixed to the bottom outer wall of the long plate, and the sliding rod passes through the sliding groove and fits at the penetration point. When the compaction plate moves, it can drive the L-shaped block to move, which will cause the inclined surface of the push block to contact the fixed block, thereby causing the push block to move upward under the squeezing force, driving the L-shaped block to move upward, which will cause the long plate to drive the sliding rod to move in the sliding groove, which will cause the sliding groove to be squeezed, driving the insert block to move out of the compaction plate and insert into the soil.

[0012] According to the above technical solution, the device further includes a shielding device, which is installed on the top of the greening pot. The shielding device includes a movable column, an auxiliary spring, a connecting block, a support block, a rotating rod, a rotating plate, a push rod, a compression spring, a transmission column, an auxiliary plate, a pressure sensor, and a baffle. The movable column is slidably installed on the inner wall of the top of the greening pot. The bottom of the auxiliary spring is fixed to the inner wall of the greening pot, and the top of the auxiliary spring is fixed to the bottom of the movable column. The connecting block is fixed to the top of the movable column, and the bottom of the connecting block is in contact with the top of the L-shaped block. The push rod is fixed to the bottom of the connecting block.

[0013] According to the above technical solution, the support block is fixed to the top of the greening pot, the rotating rod passes through the support block and is rotatably connected at the penetration point, the rotating plate is fixed to the outer wall of the rotating rod, the rotating block is fixed to the end point of the rotating rod, a torsion spring is fixed to the side wall of the rotating block, the side of the torsion spring away from the rotating block is fixed to the side wall of the support block, the transmission column passes through the rotating plate and is slidably connected at the penetration point, the auxiliary plate is fixed to the end point of the transmission column, one side of the compression spring is fixed to the side wall of the auxiliary plate, the other side of the compression spring is fixed to the side wall of the rotating plate, the baffle is fixed to the end point of the transmission column, the pressure sensor is fixed to the side wall of the rotating plate, and the pressure sensor is electrically connected to the control panel. When the L-shaped block moves upward, it will cause the L-shaped block to drive the push rod to move upward, which will cause the push rod to squeeze the rotating block, causing the rotating block to rotate, driving the rotating rod to rotate, thereby driving the blocking block to rotate.

[0014] This invention provides a green building planting structure for coastal areas. It has the following beneficial effects:

[0015] 1. This invention, by incorporating a protective device, allows the placement plate to move downwards during heavy rain or storms in coastal areas. This movement, achieved by activating a motor, extends the planter into the roof panel, protecting the plants and preventing damage from storms. Furthermore, as the placement plate extends the planter into the roof panel, it prevents pressure on the inclined blocks. Through the coordination of connecting springs, bending blocks, pressing columns, and inclined grooves, a baffle blocks the openings at the top of the roof panel, preventing excessive rainwater from entering and damaging the plants.

[0016] 2. This invention, by setting up a stabilizing device, causes the inclined surface of the transmission block to contact the through hole when the placement plate moves the green pot upwards. Under force, the block moves, allowing the compaction plate to compact the soil in the green pot, thus solving the problem of loose soil in the green pot, which easily leads to the plants being moved out of the green pot. Furthermore, while the compaction plate is compacting the soil, the cooperation of the L-shaped block, push block, fixing block, long plate, and insert block allows the insert block to be inserted into the soil, thereby creating resistance to the soil and preventing external wind from blowing the soil and plants out of the green pot and damaging the plants.

[0017] 3. This invention, by setting up a shielding device, allows the L-shaped block to press against the connecting block when it moves upward, causing the push rod to move upward and press against the rotating block, which in turn rotates the rotating rod. This allows the rotating plate to move the blocking block to shield the top of the green pot, preventing the plants and soil from being moved out of the pot and damaged. Furthermore, when the soil moves upward and presses against the blocking block, if the pressure is too great, it can cause the blocking block to move closer to the rotating plate and press against the pressure sensor. The pressure sensor then sends an electrical signal to the control panel, which in turn starts the motor, causing the green pot to extend into the roof panel and protect the plants inside. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure of the present invention;

[0019] Figure 2 This is a schematic diagram of the internal structure of the present invention;

[0020] Figure 3 For the present invention Figure 2 Enlarged schematic diagram of structure A;

[0021] Figure 4 This is a partial structural diagram of the present invention;

[0022] Figure 5 This is a schematic diagram of the structure of the greening pot of the present invention;

[0023] Figure 6 This is a partial structural diagram of the greening pot of the present invention;

[0024] Figure 7 This is a schematic diagram of the shielding device of the present invention;

[0025] Figure 8 This is a schematic diagram of the structure of the greening pot part of the present invention;

[0026] Figure 9 This is a schematic diagram of the internal structure of the compaction plate of the present invention;

[0027] Figure 10 For the present invention Figure 9 Enlarged schematic diagram of structure B;

[0028] Figure 11 For the present invention Figure 5 An enlarged schematic diagram of the C-structure.

[0029] In the diagram: 1. Roof panel; 2. Green pot; 3. Through hole; 41. Placement plate; 42. Motor; 43. Threaded rod; 44. Extrusion block; 45. Inclined block; 46. Bending block; 47. Connecting spring; 48. Baffle; 49. Extrusion column; 410. Inclined groove; 411. Control panel; 51. Transmission block; 52. Compacting plate; 53. Transmission spring; 54. L-shaped block; 55. Push block; 56. Fixing block; 57. Long plate; 58. Insert block; 59. Return spring; 510. Slide groove; 511. Slide rod; 61. Moving column; 62. Connecting block; 63. Auxiliary spring; 64. Push rod; 65. Support block; 66. Rotating rod; 67. Rotating plate; 68. Rotating block; 69. Compression spring; 610. Transmission column; 611. Auxiliary plate; 612. Blocking block; 613. Pressure sensor. Detailed Implementation

[0030] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0031] Please see Figures 1-11 One embodiment of the present invention is: a green building planting structure for coastal areas, including a roof panel 1, a greening pot 2 is provided inside the roof panel 1, a through hole 3 is provided on the top of the roof panel 1, and a protective device is provided on the roof panel 1 to protect the green plants in the greening pot 2.

[0032] The protective device includes a motor 42, a threaded rod 43, a placement plate 41, an inclined block 45, an extrusion block 44, a bending block 46, a connecting spring 47, an extrusion column 49, an inclined groove 410, a control panel 411, and a baffle 48. The motor 42 is fixed to the inner wall of the roof panel 1, the threaded rod 43 is fixed to the top output end of the motor 42, the placement plate 41 is threaded to the outer wall of the threaded rod 43, and the placement plate 41 is slidably installed on the inner wall of the roof panel 1. The green pot 2 is detachably installed on the top of the placement plate 41, and the inclined block 45 penetrates the side wall of the roof panel 1, with the penetration point sliding... The system is dynamically connected, with the extrusion block 44 fixed to the top of the placement plate 41, the bending block 46 fixed to the side wall of the inclined block 45, one side of the connecting spring 47 fixed to the side wall of the roof panel 1, and the other side of the connecting spring 47 fixed to the side wall of the bending block 46. The baffle 48 is slidably installed on the top of the roof panel 1, and the baffle 48 has an inclined groove 410. The extrusion column 49 is fixed to the bottom outer wall of the bending block 46, and the outer wall of the extrusion column 49 is in contact with the inner wall of the inclined groove 410. The control panel 411 is fixed to the side wall of the roof panel 1, and the control panel 411 is electrically connected to the motor 42.

[0033] When used in coastal areas, in the event of heavy rain or storms, starting the motor 42 can move the placement plate 41 downwards, allowing the green pot 2 to extend into the roof panel 1, thereby protecting the green plants in the green pot 2 and solving the problem of damage to the green plants caused by storms or heavy rain.

[0034] Two sets of baffles 48 are provided, and the two sets of baffles 48 are symmetrically arranged with the center line in the vertical direction of the roof panel 1 as the axis of symmetry. When the placement plate 41 drives the green pot 2 into the roof panel 1, the placement plate 41 will not press the inclined block 45. Through the cooperation of the connecting spring 47, bending block 46, pressing column 49 and inclined groove 410, the baffles 48 can block the through hole 3 at the top of the roof panel 1, thereby preventing a large amount of rainwater from entering the roof panel 1 and solving the problem of a large amount of rainwater coming into contact with the green plants and causing damage to the green plants.

[0035] In this embodiment, when the plants need to be displayed, starting the motor 42 causes the threaded rod 43 to rotate forward, which in turn moves the potted plants 2 on the placement plate 41 upward. As the placement plate 41 moves upward, it moves the pressing block 44 upward. When the pressing block 44 moves upward and contacts the inclined surface of the inclined block 45, the inclined block 45 is compressed and moves outward from the roof panel 1. This causes the bending block 46 to move, stretching the connecting spring 47. As the bending block 46 moves, it causes the pressing column 49 to move within the inclined groove 410, pressing against the inner wall of the inclined groove 410. This compresses the two sets of baffles 48, causing them to move away from each other and exposing the through hole 3. Thus, as the placement plate 41 continues to move upward, the green pot 2 can be removed from the through hole 3, and the green plants can be removed from the roof panel 1 for display. In the event of heavy rain or storms, the motor 42 can be controlled to reverse the threaded rod 43, causing the placement plate 41 on the threaded rod 43 to move downward, which can move the green pot 2 downward into the roof panel 1. When the placement plate 41 moves downward and does not contact the inclined block 45, the connecting spring 47 is in a stretched state, which can drive the bending block 46 to reset, and the pressing column 49 to reset in the inclined groove 410. This can drive the two sets of baffles 48 to move closer to each other, blocking and sealing the through hole 3, preventing a large amount of rainwater from entering the roof panel 1 and causing damage to the green plants.

[0036] Please see Figures 1-11 Based on the above embodiments, in another embodiment of the present invention, a stabilizing device is provided on the greening pot 2 to prevent the green plants from detaching from the soil. The stabilizing device includes a transmission block 51, a compaction plate 52, a transmission spring 53, an L-shaped block 54, a fixing block 56, a push block 55, a long plate 57, an insert block 58, a return spring 59, a sliding groove 510, and a sliding rod 511. The transmission block 51 passes through the side wall of the greening pot 2 and is slidably connected at the penetration point. The compaction plate 52 is fixed to the side wall of the transmission block 51. One side of the transmission spring 53 is fixed to the side wall of the compaction plate 52, and the other side of the transmission spring 53 is fixed to the greening pot 2. Inside the compaction plate 52, an L-shaped block 54 passes through the top of the compaction plate 52 and is slidably connected at the point of penetration. A push block 55 is fixed to the outer wall of the L-shaped block 54. A fixing block 56 is fixed to the top of the side wall of the greening pot 2. A long plate 57 is fixed to the bottom of the L-shaped block 54. An insert block 58 passes through the side wall of the compaction plate 52 and is slidably connected at the point of penetration. A groove 510 is opened on the insert block 58. The top of the return spring 59 is fixed to the bottom of the long plate 57. The bottom of the return spring 59 is fixed to the inner wall of the compaction plate 52. A sliding rod 511 is fixed to the bottom outer wall of the long plate 57. The sliding rod 511 passes through the groove 510 and fits at the point of penetration.

[0037] When the placement plate 41 moves the green pot 2 upward, the inclined surface of the transmission block 51 will contact the through hole 3 and move under force, which enables the compaction plate 52 to compact the soil in the green pot 2, solving the problem of loose soil in the green pot 2, which easily causes the green plants to be moved out of the green pot 2.

[0038] Furthermore, while the compaction plate 52 compacts the soil, the L-shaped block 54, the push block 55, the fixing block 56, the long plate 57 and the insert block 58 work together to insert the insert block 58 into the soil, thereby creating resistance to the soil and preventing the external wind from blowing the soil and green plants in the greening pot 2 away and damaging the green plants.

[0039] It also includes a shielding device, which is installed on the top of the greening pot 2. The shielding device includes a movable column 61, an auxiliary spring 63, a connecting block 62, a support block 65, a rotating rod 66, a rotating plate 67, a push rod 64, a rotating block 68, a compression spring 69, a transmission column 610, an auxiliary plate 611, a pressure sensor 613, and a blocking block 612. The movable column 61 is slidably installed on the inner wall of the top of the greening pot 2. The bottom of the auxiliary spring 63 is fixed to the inner wall of the greening pot 2, and the top of the auxiliary spring 63 is fixed to the bottom of the movable column 61. The connecting block 62 is fixed to the top of the movable column 61, and the bottom of the connecting block 62 is in contact with the top of the L-shaped block 54. The push rod 64 is fixed to the bottom of the connecting block 62, and the support block 65 is fixed to the top of the greening pot 2. A moving rod 66 passes through a support block 65 and is rotatably connected at the point of penetration. A rotating plate 67 is fixed to the outer wall of the rotating rod 66. A rotating block 68 is fixed to the end of the rotating rod 66. A torsion spring is fixed to the side wall of the rotating block 68. The side of the torsion spring away from the rotating block 68 is fixed to the side wall of the support block 65. A transmission column 610 passes through a rotating plate 67 and is slidably connected at the point of penetration. An auxiliary plate 611 is fixed to the end of the transmission column 610. One side of a compression spring 69 is fixed to the side wall of the auxiliary plate 611, and the other side of the compression spring 69 is fixed to the side wall of the rotating plate 67. A blocking block 612 is fixed to the end of the transmission column 610. A pressure sensor 613 is fixed to the side wall of the rotating plate 67. The pressure sensor 613 is electrically connected to the control panel 411.

[0040] When the L-shaped block 54 moves upward, it can squeeze the connecting block 62, causing the push rod 64 to move upward, squeezing the rotating block 68, and causing the rotating rod 66 to rotate. This allows the rotating plate 67 to drive the blocking block 612 to cover the top of the green pot 2, thus preventing the green plants and soil from being moved out of the green pot 2 and causing damage to the green plants.

[0041] Furthermore, when the soil moves upward and squeezes the blocking block 612, if the squeezing force is too great, it can cause the blocking block 612 to move closer to the rotating plate 67 under the squeezing force, and squeeze the pressure sensor 613. The pressure sensor 613 will then emit an electrical signal under the squeezing force, and transmit the electrical signal to the control panel 411. The control panel 411 will then control the motor 42 to start, which will cause the green pot 2 to extend into the roof panel 1 to protect the green plants in the green pot 2.

[0042] In this embodiment, during operation: when the placement plate 41 moves the green pot 2 upward, and the green pot 2 moves to the point where the inclined surface of the transmission block 51 contacts the through hole 3, as the green pot 2 continues to move upward, the transmission block 51 will be compressed and moved into the green pot 2, thereby driving the compaction plate 52 to move. The compaction plate 52 can compact the soil in the green pot 2. When the compaction plate 52 moves, the transmission spring 53 will be stretched. When the compaction plate 52 moves, it can drive the L-shaped block 54 to move. When the push block 55 on the L-shaped block 54 moves to the inclined surface and contacts the fixed block 56, the push block 55 will be compressed and move upward, driving the L-shaped block 54 to move upward. When the L-shaped block 54 moves upward, it can drive the long plate 57 to move upward. When the long plate 57 moves upward, it can stretch the return spring 59. This allows the sliding rod 511 to move within the chute 510, compressing the inner wall of the chute 510 and subjecting it to compressive force. This allows the insert block 58 to move outward from the compaction plate 52 and be inserted into the soil. When the placement plate 41 moves the green pot 2 into the roof panel 1, the transmission block 51 is no longer subject to compressive force. Because the transmission spring 53 is in a stretched state, it can drive the compaction plate 52 to reset. When the compaction plate 52 resets, the push block 55 will not contact the fixed block 56. Because the reset spring 59 is in a stretched state, it can drive the L-shaped block 54 to reset. When the L-shaped block 54 resets, the long plate 57 can drive the sliding rod 511 downward, causing the sliding rod 511 to compress the chute 510 and allowing the insert block 58 to extend into the compaction plate 52 for reset, thus facilitating the subsequent addition of soil.

[0043] When the L-shaped block 54 moves upward, it presses against the connecting block 62, causing the connecting block 62 to move upward. This causes the moving column 61 to move upward, stretching the auxiliary spring 63. The upward movement of the connecting block 62 drives the push rod 64 to move upward, pressing against the rotating block 68 and causing it to rotate upward. This upward rotation of the rotating block 68 compresses the torsion spring, causing it to rotate the rotating rod 66. The rotation of the rotating rod 66 then causes the rotating plate 67 to rotate downward. Through the transmission column 610, this drives the blocking block 612 to move downward. The L-shaped block 54 rotates downwards, thus blocking the soil in the green pot 2. When the L-shaped block 54 moves downwards to reset, it does not compress the connecting block 62. Because the auxiliary spring 63 is in a stretched state, it can drive the moving column 61 downwards, which in turn drives the connecting block 62 downwards. When the connecting block 62 moves downwards, the push rod 64 does not compress the rotating block 68. Because the torsion spring is in a compressed state, it can drive the rotating block 68 downwards, which in turn drives the rotating rod 66 to rotate the blocking block 612 to reset, so that the blocking block 612 does not block the green pot 2, making it convenient to replace and add soil in the green pot 2.

[0044] When the blocking block 612 blocks the soil in the green pot 2, if the outside wind is too strong, it can drag the green plant and move the soil out of the green pot 2. This will cause the soil to squeeze the bottom of the blocking block 612, which will cause the blocking block 612 to move closer to the rotating plate 67. This will cause the blocking block 612 to squeeze the pressure sensor 613. When the pressure sensor 613 is under pressure, it can send an electrical signal to the control panel 411. The control panel 411 can control the motor 42 to start, causing the threaded rod 43 to reverse and drive the placement plate 41 to move downward, so that the green pot 2 can be inserted into the roof panel 1 for protection.

[0045] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A kind of sea-green building planting structure, including roof panel (1), it is characterized in that: The roof panel (1) is provided with a green pot (2) inside. The roof panel (1) has a through hole (3) at the top. The roof panel (1) is provided with a protective device to protect the green plants in the green pot (2). The green pot (2) is provided with a stabilizing device to prevent the green plants from falling out of the soil. The protective device includes a motor (42), a threaded rod (43), a placement plate (41), an inclined block (45), an extrusion block (44), a bending block (46), a connecting spring (47), an extrusion column (49), an inclined groove (410), a control panel (411), and a baffle (48). The motor (42) is fixed to the inner wall of the roof panel (1), the threaded rod (43) is fixed to the top output end of the motor (42), the placement plate (41) is threaded to the outer wall of the threaded rod (43), the placement plate (41) is slidably installed on the inner wall of the roof panel (1), the green pot (2) is detachably installed on the top of the placement plate (41), the inclined block (45) penetrates the side wall of the roof panel (1) and is slidably connected at the penetration point, and the extrusion block (44) is fixed to the top of the placement plate (41). The bending block (46) is fixed to the side wall of the inclined block (45), one side of the connecting spring (47) is fixed to the side wall of the roof panel (1), and the other side of the connecting spring (47) is fixed to the side wall of the bending block (46). The baffle (48) is slidably installed on the top of the roof panel (1). The baffle (48) has a groove (410). The extrusion column (49) is fixed to the bottom outer wall of the bending block (46). The outer wall of the extrusion column (49) is in contact with the inner wall of the groove (410). The control panel (411) is fixed to the side wall of the roof panel (1). The control panel (411) is electrically connected to the motor (42). The stabilizing device includes a transmission block (51), a compaction plate (52), a transmission spring (53), an L-shaped block (54), a fixing block (56), a push block (55), a long plate (57), an insert block (58), a reset spring (59), a slide groove (510), and a slide rod (511); the transmission block (51) passes through the side wall of the greening pot (2) and is slidably connected at the penetration point; the compaction plate (52) is fixed to the side wall of the transmission block (51); one side of the transmission spring (53) is fixed to the side wall of the compaction plate (52), and the other side of the transmission spring (53) is fixed to the inner side of the greening pot (2); the L-shaped block (54) passes through the top of the compaction plate (52) and is slidably connected at the penetration point; The push block (55) is fixed to the outer wall of the L-shaped block (54), the fixing block (56) is fixed to the top of the side wall of the greening pot (2), the long plate (57) is fixed to the bottom of the L-shaped block (54), the insert block (58) penetrates the side wall of the compaction plate (52) and is slidably connected at the penetration point, and the groove (510) is opened on the insert block (58); The top of the reset spring (59) is fixed to the bottom of the long plate (57), the bottom of the reset spring (59) is fixed to the inner wall of the compaction plate (52), the slide rod (511) is fixed to the bottom outer wall of the long plate (57), the slide rod (511) passes through the slide groove (510), and the passage is fitted.

2. The coastal green building planting structure according to claim 1, characterized in that: It also includes a shielding device, which is set on the top of the greening pot (2). The shielding device includes a moving column (61), an auxiliary spring (63), a connecting block (62), a support block (65), a rotating rod (66), a rotating plate (67), a push rod (64), a rotating block (68), a compression spring (69), a transmission column (610), an auxiliary plate (611), a pressure sensor (613), and a blocking block (612). The moving column (61) is slidably installed on the top inner wall of the greening pot (2). The bottom of the auxiliary spring (63) is fixed to the inner wall of the greening pot (2), and the top of the auxiliary spring (63) is fixed to the bottom of the moving column (61). The connecting block (62) is fixed to the top of the moving column (61), and the bottom of the connecting block (62) is in contact with the top of the L-shaped block (54). The push rod (64) is fixed to the bottom of the connecting block (62).

3. The coastal green building planting structure according to claim 2, characterized in that: The support block (65) is fixed to the top of the greening pot (2). The rotating rod (66) passes through the support block (65) and is rotatably connected at the point of penetration. The rotating plate (67) is fixed to the outer wall of the rotating rod (66). The rotating block (68) is fixed to the end point of the rotating rod (66). A torsion spring is fixed to the side wall of the rotating block (68). The side of the torsion spring away from the rotating block (68) is fixed to the side wall of the support block (65). The transmission column (610) passes through the rotating plate (67) and... The auxiliary plate (611) is fixed to the end of the transmission column (610), one side of the compression spring (69) is fixed to the side wall of the auxiliary plate (611), the other side of the compression spring (69) is fixed to the side wall of the rotating plate (67), the blocking block (612) is fixed to the end of the transmission column (610), the pressure sensor (613) is fixed to the side wall of the rotating plate (67), and the pressure sensor (613) is electrically connected to the control panel (411).

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