CN113317140A

CN113317140A - Ground view gardens concatenation formula lawn chassis

Info

Publication number: CN113317140A
Application number: CN202110746179.5A
Authority: CN
Inventors: 童涛; 陈晓熙; 向大军; 安羽; 陈玲; 李金龙; 李明
Original assignee: Hubei Huayu Dijing Landscape Engineering Co ltd
Current assignee: Hubei Huayu Dijing Landscape Engineering Co ltd
Priority date: 2021-07-01
Filing date: 2021-07-01
Publication date: 2021-08-31
Anticipated expiration: 2041-07-01
Also published as: CN113317140B

Abstract

The invention discloses a landscape garden splicing type lawn chassis which comprises a chassis body, planting modules and splicing insertion blocks, wherein the planting modules are arranged on the chassis body; the planting module is positioned on the chassis body; a plurality of groups of splicing slots are formed in the edge of one side of the top of the chassis body at equal intervals, and a plurality of groups of splicing insertion blocks are mounted on one side wall, far away from the splicing slots, of the chassis body at equal intervals; the number of the splicing slots is the same as that of the splicing insertion blocks, and each group of the splicing insertion blocks can be respectively and movably clamped in a plurality of groups of splicing slots on the adjacent group of the chassis body; a plurality of groups of side grooves are symmetrically formed in the inner walls of the two sides of the splicing slot; a plurality of groups of reinforcing plates are symmetrically arranged on two side walls of the splicing insertion block; the number of the reinforcing plates is the same as that of the side grooves. The invention can improve the fixity between two adjacent lawn chassis and improve the drainage efficiency.

Description

Ground view gardens concatenation formula lawn chassis

Technical Field

The invention belongs to the technical field of landscaping, and particularly relates to a landscape and garden spliced lawn chassis.

Background

The greening lawn is an important part in landscape architecture, and herbaceous plants are directly planted on the land when the landscape architecture is laid out, so that the herbaceous plants are fixed in position. When the landscape architecture needs to be replanned, the herbaceous plants are difficult to use for the second time, and the land reclamation also causes the cost to be increased.

The lawn chassis is promoted to appear, and when the lawn needs to be greened, a plurality of groups of lawn chassis are transported to a specified place and directly placed according to requirements. The mobile transportation is convenient, the land is not required to be reformed, and the use cost is reduced.

However, each lawn chassis is an independent unit, and two adjacent lawn chassis cannot be fixedly connected. The lawn is easy to be influenced by external force to cause displacement, so that a gap is formed between two adjacent lawn chassis.

Patent with application number CN202021995007.9 discloses a splice unit for artificial turf lays, it sets up first splice plate respectively through both ends about the base plate, the front and back both ends set up the second splice plate respectively, and set up a plurality of first coupling mechanism on the first splice plate of base plate right-hand member, set up the second coupling mechanism corresponding with first coupling mechanism on the first splice plate of left end, make and to carry out the concatenation operation between a plurality of splice units through first coupling mechanism and second coupling mechanism, can improve the convenience of stability and dismouting, but above-mentioned splice unit can carry out the drainage when using, but can't control drainage speed, the problem that the drainage is faster or slower can appear, all do not do benefit to the growth of plant on the lawn.

Disclosure of Invention

Aiming at the problems, the invention provides a landscape garden splicing type lawn chassis which comprises a chassis body, a planting module and splicing insertion blocks; the planting module is positioned on the chassis body; a plurality of groups of splicing slots are formed in the edge of one side of the top of the chassis body at equal intervals, and a plurality of groups of splicing insertion blocks are mounted on one side wall, far away from the splicing slots, of the chassis body at equal intervals; the number of the splicing slots is the same as that of the splicing insertion blocks, and each group of the splicing insertion blocks can be respectively and movably clamped in a plurality of groups of splicing slots on the adjacent group of the chassis body; a plurality of groups of side grooves are symmetrically formed in the inner walls of the two sides of the splicing slot; a plurality of groups of reinforcing plates are symmetrically arranged on two side walls of the splicing insertion block; the number of the reinforcing plates is the same as that of the side grooves, and each group of reinforcing plates can be movably clamped in the corresponding side grooves on the adjacent group of chassis bodies.

Further, a water collecting tray is arranged below the chassis body, and two groups of through holes are symmetrically formed in edges of two sides of the top of the water collecting tray.

Further, two sets of spacing picture peg are installed to chassis body bottom both sides edge symmetry, and are two sets of spacing picture peg bottom can be respectively through two sets of through-hole activities run through to in the water catch bowl.

Furthermore, a thick water outlet is formed in the center of the bottom of the chassis body, and a plurality of groups of thin water outlets are symmetrically formed in two sides of the thick water outlet; and a first sliding chute is arranged between the coarse water outlet and the groups of fine water outlets on one side.

Furthermore, a plurality of groups of bearing springs are installed at the bottom of the chassis body, and the bottoms of the plurality of groups of bearing springs are installed at the top of the water collecting tray.

Further, the planting module comprises a gravel layer and a coarse sand layer; the top of the chassis body is provided with a groove, the gravel layer is positioned at the bottom of the groove, and the coarse sand layer is positioned at the top of the gravel layer; the top of the coarse sand layer is provided with a soil base layer, and the top of the soil base layer is provided with a planting layer.

Further, the planting layer comprises a plurality of groups of water permeable lugs; the groups of the water permeable lugs are distributed on the top of the soil base layer in a rectangular array, and each group of the water permeable lugs is provided with a plurality of groups of water permeable holes; the bottoms of the water permeable holes are communicated with the soil base layer; the water permeable lugs are of a frustum pyramid structure, the water permeable lugs are combined to form a water permeable layer, and the top of the water permeable layer is covered with a nutrient soil layer.

Furthermore, a self-drainage control module is arranged between the two groups of limiting inserting plates, and comprises an inclined plane plate, a first sliding block and a supporting rod; the inclined plane plate is arranged at the bottom of the chassis body and is positioned on one side of the coarse water outlet, which is far away from the first sliding chute; the bottom of the inclined plane plate is obliquely arranged, and one end, close to the thick water outlet, of the inclined plane plate is higher than the other end of the inclined plane plate; the bottom of the first sliding block is connected in the second sliding groove in a sliding mode, and the top of the first sliding block is provided with a supporting rod mounting plate; one end of the abutting rod is installed on the abutting rod installation plate, and the other end of the abutting rod is attached to the bottom of the inclined plane plate in a sliding mode; the supporting rod mounting plate is provided with a buffer spring, the buffer spring is provided with a sealing plate, and the top of the sealing plate is attached to the coarse water outlet.

Furthermore, a return spring is installed on the inner wall of one side, away from the first sliding block, of the second sliding groove, and the other end of the return spring is installed on the side wall of the first sliding block.

Furthermore, a chute water leakage hole is formed in the inner wall of the bottom of the second chute, and the bottom of the chute water leakage hole is communicated with the inner cavity of the water collecting tray.

The invention has the beneficial effects that:

1. when splicing a plurality of groups of chassis bodies, the splicing insertion blocks on one group of chassis bodies are inserted into the splicing insertion grooves on the adjacent group of chassis bodies. The process is simple and quick, and the splicing efficiency is improved. And through the joint relation between reinforcing plate and the side channel, the fixity between concatenation inserted block and the concatenation slot has been improved.

2. When the accumulated water in the chassis body is less, the water is drained through the fine drainage port, and the herbaceous plants are prevented from being dehydrated due to too fast water loss. When the water volume in the chassis body increases, the chassis body sinks due to the increase of the weight. Then the abutting rod drives the sealing plate to move to be separated from the thick discharge port, accumulated water can be discharged through the thick discharge port, and the accumulated water discharge speed is increased. When the accumulated water is discharged, the chassis body rises due to the reduction of the weight, so that the sealing plate is reset to block the thick discharge port again. Therefore, the automatic drainage function can be realized on the chassis body without manual operation.

3. The lug that permeates water that is located the nutrition soil layer below is prismoid shape structure to the lateral wall and the top of the lug that permeates water all are provided with the hole of permeating water, when ponding appears on the nutrition soil layer, through this emission efficiency that has improved of the mode of "three-dimensional emission". And the characteristic that the permeable lugs are arranged at equal intervals is utilized, so that the herbaceous plants planted at the tops of the permeable lugs are arranged more neatly, and the ornamental value is improved.

Drawings

Fig. 1 shows a schematic structural view of a lawn chassis according to an embodiment of the invention;

FIG. 2 shows a schematic cross-sectional view of a lawn chassis according to an embodiment of the invention;

FIG. 3 shows a schematic bottom view of a chassis body in an embodiment in accordance with the invention;

FIG. 4 shows a schematic cross-sectional view of a planting layer in an embodiment in accordance with the invention;

FIG. 5 is a schematic structural diagram of a self-draining control module according to an embodiment of the present invention;

FIG. 6 shows a schematic top view of a second runner in an embodiment in accordance with the invention;

FIG. 7 shows a schematic structural view of a water collection tray according to an embodiment of the invention;

fig. 8 shows a schematic structural view of the inside of a water collection tray according to an embodiment of the present invention;

FIG. 9 shows an enlarged schematic view of the circle A of FIG. 1 in accordance with an embodiment of the present invention;

FIG. 10 is a schematic structural diagram of a splice plug in accordance with an embodiment of the present invention;

fig. 11 shows a schematic structural diagram of two adjacent chassis bodies after being spliced according to an embodiment of the invention.

In the figure: 100. a chassis body; 110. a fine water outlet; 120. a coarse water outlet; 130. a first chute; 200. a planting module; 210. a gravel layer; 220. a coarse sand layer; 230. a soil base layer; 240. planting a layer; 241. a water permeable projection; 242. water permeable holes; 243. a nutrient soil layer; 300. a limiting inserting plate; 310. a load bearing spring; 320. a self-draining control module; 321. an inclined plane plate; 322. a first slider; 323. a support rod mounting plate; 324. a support rod; 325. a buffer spring; 326. a sealing plate; 327. a second slider; 400. a water collection tray; 410. a plug board limiting box; 420. a water inlet; 430. a second chute; 431. a return spring; 432. a chute water leakage hole; 440. a through hole; 450. a sealing plug; 500. splicing the slots; 510. a side groove; 600. splicing the insert blocks; 610. a reinforcing plate.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The embodiment of the invention provides a spliced lawn chassis for landscape gardens. Comprises a chassis body 100, a planting module 200, a self-drainage control module 320, a water collecting tray 400 and a splicing insertion block 600. Illustratively, as shown in fig. 1, 2 and 3, a groove is formed at the top of the chassis body 100, and the planting module 200 is located in the groove. The chassis body 100 has a rectangular structure. Because the chassis body 100 is a rectangular structure, when the two sets of chassis bodies 100 are spliced, the two side walls close to each other can be completely attached to each other.

The water collecting tray 400 is located under the chassis body 100, and two sets of through holes 440 are symmetrically formed in edges of two sides of the top of the water collecting tray 400. A second sliding groove 430 is arranged between the two sets of through holes 440. The water collecting tray 400 collects the accumulated water discharged from the inside of the chassis body 100.

Two sets of spacing picture peg 300 are installed to chassis body 100 bottom both sides edge symmetry, and are two sets of spacing picture peg 300 bottom can be respectively through two sets of through-holes 440 activity run through to in the water catch bowl 400. When ponding appears in the chassis body 100, the water moves downwards due to the increase of weight, is inserted into the through hole 440 through the limiting inserting plate 300 and limits the chassis body 100, so that the chassis body 100 moves vertically downwards, and the chassis body 100 is prevented from shifting when descending due to the influence of external force. Is convenient for drainage work.

The self-drainage control module 320 is located between the two sets of limiting insertion plates 300, and the self-drainage control module 320 is slidably attached to the output end of the chassis body 100. The self-drainage control module 320 can automatically drain water when rainwater is present in the chassis body 100.

A plurality of groups of splicing slots 500 are arranged at the edge of one side of the top of the chassis body 100 at equal intervals, and a plurality of groups of splicing insertion blocks 600 are arranged on one side wall of the chassis body 100 far away from the splicing slots 500 at equal intervals. The number of the splicing slots 500 is the same as that of the splicing insertion blocks 600, and each group of the splicing insertion blocks 600 can be respectively and movably clamped in a plurality of groups of splicing slots 500 on the adjacent group of the chassis body 100.

Firstly, the splicing insertion blocks 600 on one group of chassis bodies 100 are inserted into the splicing insertion grooves 500 of the adjacent group of chassis bodies 100, and then the splicing insertion blocks 600 on the other group of chassis bodies 100 are inserted into the splicing insertion grooves 500 on the group of chassis bodies 100, so that the installation work is simple and rapid, and the installation efficiency is improved. Meanwhile, because the chassis body 100 has a rectangular structure, the two adjacent sets of chassis bodies 100 are attached to each other at the two outer side walls close to each other. Not only can play the same effect with traditional lawn chassis to after dismantling, can stack and pile up a plurality of groups chassis body 100, be convenient for transportation and storage.

The bottom center of the chassis body 100 is provided with a thick water outlet 120, and two sides of the thick water outlet 120 are symmetrically provided with a plurality of groups of thin water outlets 110. And a first sliding chute 130 is arranged between the thick water outlet 120 and the plurality of groups of thin water outlets 110 on one side.

The bottom of the chassis body 100 is provided with a plurality of groups of bearing springs 310, the plurality of groups of bearing springs 310 are arranged at equal intervals, and the bottoms of the plurality of groups of bearing springs 310 are all arranged on the top of the water collecting tray 400. The load-bearing spring 310 can facilitate the lifting operation of the chassis body 100.

The planting module 200 includes a gravel layer 210 and a coarse sand layer 220. Illustratively, the gravel layer 210 is positioned at the bottom of the groove and the grit layer 220 is positioned at the top of the gravel layer 210. A soil base layer 230 is arranged on the top of the coarse sand layer 220, and a planting layer 240 is arranged on the top of the soil base layer 230.

The planting layer 240 includes a plurality of groups of water permeable projections 241. For example, as shown in fig. 4, a plurality of groups of the water permeable protrusions 241 are distributed on the top of the soil base layer 230 in a rectangular array, and each group of the water permeable protrusions 241 is provided with a plurality of groups of water permeable holes 242. The bottom of the water permeable holes 242 communicate with the soil base layer 230. The water permeable bumps 241 are in a frustum pyramid structure, and the number of the water permeable bumps 241 is not less than four groups. The water permeable layer can be formed by combining a plurality of groups of the water permeable lugs 241, and the top of the water permeable layer is covered with a nutrient soil layer 243.

Firstly, herbaceous plants required for greening are respectively planted on the nutrient soil layers 243 at the tops of the groups of the water-permeable bumps 241, and the herbaceous plants are provided with required nutrients through the nutrient soil layers 243. And when a plurality of groups of chassis bodies 100 are spliced, the effect of greening display is achieved by the herbaceous plants planted in the nutrient soil layer 243. By utilizing the characteristic that the water permeable lugs 241 are arranged at equal intervals, the arrangement of the herbaceous plants is more orderly, and the ornamental value of the herbaceous plants is improved.

When a small amount of water is accumulated in the chassis body 100, part of the accumulated water is first absorbed through the nutrient soil layer 243 for supplying herbaceous plants. And the remaining water drops through the water permeable holes 242 into the underlying soil bed 230. And after being filtered and absorbed by the soil base layer 230, the coarse sand layer 220 and the gravel layer 210 in sequence, the residual accumulated water can be slowly discharged through the fine water discharge port 110, so that the phenomenon of water shortage of herbaceous plants caused by too high water discharge speed is avoided. Meanwhile, the water permeable bump 241 below the nutrient soil layer 243 is of a frustum pyramid structure, the side wall and the top of the water permeable bump 241 are provided with water permeable holes 242, and when water is accumulated on the nutrient soil layer 243, the water discharge efficiency is improved through the three-dimensional discharge mode.

The self-draining control module 320 includes a slope plate 321, a first slider 322, an abutting rod 324, a buffer spring 325 and a sealing plate 326. For example, as shown in fig. 5, the bevel plate 321 is installed at the bottom of the chassis body 100 and is located at a side of the rough drainage opening 120 away from the first sliding groove 130. The bottom of the inclined plate 321 is inclined, and the height of one end near the coarse water outlet 120 is higher than that of the other end. The bottom of the first sliding block 322 is slidably connected in the second sliding groove 430, and the top is provided with a support rod mounting plate 323. One end of the abutting rod 324 is mounted on the abutting rod mounting plate 323, and the other end is attached to the bottom of the inclined plate 321 in a sliding manner. The buffer spring 325 is installed on the top of the support rod installation plate 323, the sealing plate 326 is installed on the top of the buffer spring 325, and the top of the sealing plate 326 is attached to the bottom of the coarse drain opening 120. The side of the sealing plate 326 far away from the inclined plane 321 is provided with a second sliding block 327, and the top of the second sliding block 327 is slidably connected in the first sliding groove 130.

For example, as shown in fig. 6, a return spring 431 is mounted on an inner wall of the second sliding chute 430 on a side away from the first sliding block 322, and the other end of the return spring 431 is mounted on a side wall of the first sliding block 322. A chute water leakage hole 432 is formed in the inner wall of the bottom of the second chute 430, and the bottom of the chute water leakage hole 432 is communicated with the inner cavity of the water collecting tray 400.

When the amount of water accumulated in the groove increases due to weather, the chassis body 100 sinks vertically due to the increase of the overall weight. While the chassis body 100 is sinking vertically, the resisting rod 324 slides from the lower side of the bottom inclined plane of the inclined plane plate 321 to the other side, and then the sealing plate 326 attached to the coarse drain opening 120 is driven to move towards the first sliding groove 130 by the sliding of the resisting rod 324, so that the sealing effect on the coarse drain opening 120 is lost, and the accumulated water can be discharged through the coarse drain opening 120. The discharge speed of the accumulated water is improved, and the damage to the herbaceous plants due to the fact that the accumulated water is discharged too slowly is avoided. When the accumulated water in the groove is discharged, the weight of the chassis body 100 is reduced, and the chassis body 100 is vertically lifted under the action of the load bearing spring 310. Then, the first slider 322 is pushed toward the inclined plane 321 by the elastic force of the return spring 431, and the abutting rod 324 moves to the lower end of the inclined plane 321. Meanwhile, the sealing plate 326 is attached below the coarse drain opening 120 again under the driving of the support rod mounting plate 323, and the sealing function of the coarse drain opening 120 is achieved again. Therefore, the chassis body 100 can realize the function of automatic drainage without manual operation.

Illustratively, as shown in fig. 7 and 8, a water inlet 420 is formed at the top of the water collecting tray 400, and the bottom of the water inlet 420 is communicated with the inner cavity of the water collecting tray 400. Two groups of inserting plate limiting boxes 410 are fixedly installed in the inner cavity of the water collecting tray 400, and the two groups of inserting plate limiting boxes 410 are respectively positioned under the two groups of through holes 440. The bottoms of the two sets of limiting insertion plates 300 can be respectively and movably clamped in the two sets of insertion plate limiting boxes 410. A water outlet is formed in one side wall of the water collecting tray 400, and a sealing plug 450 is movably clamped on the water outlet.

The accumulated water discharged from the fine outlet 110 or the coarse outlet 120 enters the inner cavity of the water collecting tray 400 through the water inlet 420, thereby avoiding waste of water resources. And when the chassis body 100 is moved up and down due to the weight change, the limiting insertion plate 300 is vertically moved due to the limiting function of the insertion plate limiting box 410, so that the chassis body 100 is also vertically moved, and the chassis body 100 is prevented from being shifted due to external force during the lifting movement.

For example, as shown in fig. 9, 10 and 11, a plurality of sets of side grooves 510 are symmetrically formed on inner walls of two sides of the splicing insertion groove 500, and the plurality of sets of side grooves 510 located on the same side are arranged at equal intervals. A plurality of groups of reinforcing plates 610 are symmetrically arranged on two side walls of the splicing insertion block 600, and a plurality of groups of reinforcing plates 610 positioned on the same side are arranged at equal intervals. The number of the reinforcing plates 610 is the same as that of the side grooves 510, and each group of the reinforcing plates 610 can be movably clamped in each group of the side grooves 510 corresponding to the adjacent group of the chassis body 100.

When the splice plug 600 is plugged into the splice slot 500 of an adjacent chassis body 100, the sets of reinforcing plates 610 on both sides thereof are plugged into the corresponding sets of side slots 510. Thereby improving the fixation between the two sets of chassis bodies 100.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. The utility model provides a ground view gardens concatenation formula lawn chassis which characterized in that: comprises a chassis body (100), a planting module (200) and a splicing plug block (600); the planting module (200) is positioned on the chassis body (100); a plurality of groups of splicing slots (500) are formed in the edge of one side of the top of the chassis body (100) at equal intervals, and a plurality of groups of splicing insertion blocks (600) are arranged on one side wall, far away from the splicing slots (500), of the chassis body (100) at equal intervals; the number of the splicing slots (500) is the same as that of the splicing insertion blocks (600), and each group of splicing insertion blocks (600) can be movably clamped in a plurality of groups of splicing slots (500) on the adjacent group of chassis bodies (100) respectively; a plurality of groups of side grooves (510) are symmetrically formed in the inner walls of the two sides of the splicing slot (500); a plurality of groups of reinforcing plates (610) are symmetrically arranged on two side walls of the splicing insertion block (600); the number of the reinforcing plates (610) is the same as that of the side grooves (510), and each group of the reinforcing plates (610) can be movably clamped in each group of the side grooves (510) corresponding to the adjacent group of the chassis body (100).

2. The landscape architecture splicing type lawn chassis of claim 1, wherein: a water collecting tray (400) is arranged below the chassis body (100), and two groups of through holes (440) are symmetrically formed in the edges of two sides of the top of the water collecting tray (400).

3. The spliced lawn chassis for landscape architecture as claimed in claim 2, wherein: two sets of spacing picture peg (300) are installed to chassis body (100) bottom both sides edge symmetry, and are two sets of spacing picture peg (300) bottom can be respectively through two sets of through-holes (440) activity run through to in the water catch bowl (400).

4. The spliced lawn chassis for landscape architecture as claimed in claim 3, wherein: a thick water outlet (120) is formed in the center of the bottom of the chassis body (100), and a plurality of groups of thin water outlets (110) are symmetrically formed in two sides of the thick water outlet (120); and a first sliding chute (130) is arranged between the coarse water outlet (120) and a plurality of groups of fine water outlets (110) on one side.

5. The landscape architecture splicing type lawn chassis of claim 4, wherein: a plurality of groups of bearing springs (310) are installed at the bottom of the chassis body (100), and the bottoms of the bearing springs (310) are installed at the top of the water collecting tray (400).

6. The landscape architecture splicing type lawn chassis of claim 1, wherein: the planting module (200) comprises a gravel layer (210) and a coarse sand layer (220); the top of the chassis body (100) is provided with a groove, the gravel layer (210) is positioned at the bottom of the groove, and the coarse sand layer (220) is positioned at the top of the gravel layer (210); the top of the coarse sand layer (220) is provided with a soil base layer (230), and the top of the soil base layer (230) is provided with a planting layer (240).

7. The landscape architecture splicing type lawn chassis of claim 6, wherein: the planting layer (240) comprises a plurality of groups of water permeable lugs (241); the groups of the water permeable lugs (241) are distributed on the top of the soil base layer (230) in a rectangular array, and each group of the water permeable lugs (241) is provided with a plurality of groups of water permeable holes (242); the bottoms of the water permeable holes (242) are communicated with the soil base layer (230); the water permeable lugs (241) are of a frustum pyramid structure, a plurality of groups of water permeable lugs (241) are combined to form a water permeable layer, and the top of the water permeable layer is covered with a nutrient soil layer (243).

8. The landscape architecture splicing type lawn chassis of claim 4, wherein: a self-drainage control module (320) is arranged between the two groups of limiting inserting plates (300), and the self-drainage control module (320) comprises an inclined plane plate (321), a first sliding block (322) and a propping rod (324); the inclined plane plate (321) is arranged at the bottom of the chassis body (100) and is positioned on one side of the coarse drainage outlet (120) far away from the first sliding chute (130); the bottom of the inclined plane plate (321) is obliquely arranged, and one end close to the coarse water outlet (120) is higher than the other end; the bottom of the first sliding block (322) is connected in the second sliding groove (430) in a sliding manner, and the top of the first sliding block is provided with a supporting rod mounting plate (323); one end of the abutting rod (324) is mounted on the abutting rod mounting plate (323), and the other end of the abutting rod (324) is attached to the bottom of the inclined plane plate (321) in a sliding manner; the supporting rod mounting plate (323) is provided with a buffer spring (325), the buffer spring (325) is provided with a sealing plate (326), and the top of the sealing plate (326) is attached to the coarse water outlet (120).

9. The landscape architecture splicing type lawn chassis of claim 8, wherein: and a return spring (431) is arranged on the inner wall of one side of the second sliding chute (430) far away from the first sliding block (322), and the other end of the return spring (431) is arranged on the side wall of the first sliding block (322).

10. The landscape architecture splicing type lawn chassis of claim 9, wherein: and a chute water leakage hole (432) is formed in the inner wall of the bottom of the second chute (430), and the bottom of the chute water leakage hole (432) is communicated with the inner cavity of the water collecting tray (400).