CN113016402B - Wall structure of house building - Google Patents

Abstract

The application discloses a wall structure of a house building, which relates to the technical field of house buildings and aims to solve the problem that plants on the wall are rotten due to excessive accumulated water; the bottom of the flowerpot is connected with a water storage box which is communicated with the bottom of the flowerpot; the outer wall body is provided with a control assembly, and the control assembly comprises a rotating rod rotatably arranged on the outer wall body and a controller for controlling the rotating rod to rotate; the controller is connected with a humidity sensor, the humidity sensor is arranged on the outer wall body, and the humidity sensor triggers the controller to drive the rotating rod to rotate forward by 90 degrees or rotate reversely by 90 degrees; the retaining box includes the extension, and the extension is connected with the water receiving box towards one side of flowerpot, and the water receiving mouth has been seted up to one side that the water receiving box is close to the flowerpot, and when the flowerpot corotation was 90, the water receiving box was located the below of flowerpot. The flowerpot has the advantages that the opening of the flowerpot is not upward, and rainwater flows into the water receiving box along the outer wall of the flowerpot, so that the rot condition of plant roots is reduced.

Description

Wall structure of house building

Technical Field

The application relates to the technical field of house buildings, in particular to a wall structure of a house building.

Background

The building construction provides the user with living, production, work or other movable entities, and comprises the main load-bearing members of the building, such as beams, columns, walls, etc. After the traditional wall structure is built, the wall surface is monotonous, and the function of green and environment protection is lacking.

In order to improve the greening effect of wall body, present wall body structure is described in patent of grant bulletin number CN207794423U, including wall body and green planting groove, the outside longitudinal distribution of wall body has a plurality of green planting grooves, has seted up the water inlet with roof parallel and level on the top of wall body, the fixed water-absorbing partition material that is provided with in middle part of planting groove of green, the nutrient soil that fills on the water-absorbing partition material, the below sets up to the cistern, the top of cistern is provided with water delivery port and gap, the intercommunication drain pipe on the water delivery port, the water delivery port that corresponds in the planting groove of green planting at the top with the water inlet intercommunication at wall body top. When raining, the rainwater flowing down on the roof enters the green planting groove through the drain pipe, and part of the rainwater is stored in the reservoir to provide a water source for green plants.

With respect to the related art, the inventor considers that rainwater also enters the green planting groove when the rainwater rains, if the rainwater rains continuously for several days or the precipitation amount of the rainwater is large, the water accumulation condition occurs in the green planting groove, and the water accumulation of the green planting groove needs to enter the reservoir through the water absorption and separation material, so that the water accumulation discharge speed in the green planting groove is slower, and the root of the plant is rotten due to the water accumulation.

Disclosure of Invention

In order to solve the problem that plants on a wall body are rotten due to excessive accumulated water, the application provides a wall body structure of a house building.

In a first aspect, the present application provides a wall structure of a building, which adopts the following technical scheme:

the wall structure of the house building comprises an outer wall body, wherein a flowerpot is arranged on the outer wall body, an opening of the flowerpot is coated with gauze, and a planting opening for plants to extend out of the flowerpot is formed in the gauze;

the flowerpot is characterized in that a water outlet hole is formed in the bottom of the flowerpot, a water storage box is connected to the bottom of the flowerpot and communicated with the bottom of the flowerpot, and a water absorption strip is connected between the water storage box and the flowerpot;

the flowerpot is characterized in that a control assembly for controlling the rotation of the flowerpot is arranged on the outer wall body, the control assembly comprises a rotating rod rotatably arranged on the outer wall body and a controller for controlling the rotating rod to rotate, the controller is arranged on the outer wall body, a plurality of flowerpots are uniformly distributed along the length direction of the rotating rod, and a plurality of rotating rods are arranged along the height direction of the outer wall body;

the controller is connected with a humidity sensor, the humidity sensor is arranged on the outer wall body, and the humidity sensor triggers the controller to drive the rotating rod to rotate forward by 90 degrees or rotate reversely by 90 degrees;

the water storage box comprises an extension part, one side of the extension part, which faces the flowerpot, is connected with a water receiving box, the water receiving box is communicated with the water storage box, one side, close to the flowerpot, of the water receiving box is provided with a water receiving port, a gap is reserved between the water receiving box and the outer side wall of the flowerpot, and when the flowerpot rotates forward by 90 degrees, the water receiving box is located below the flowerpot.

By adopting the technical scheme, when raining, rainwater enters the flowerpot, redundant rainwater can enter the water storage box, the humidity in the air is continuously increased, when the numerical value of the humidity sensor is increased to a set numerical value, the controller is triggered by the humidity, so that the rotating rod is driven by the controller to rotate by 90 degrees in a forward direction, the flowerpot rotates by 90 degrees along with the rotating rod, the opening of the flowerpot is not kept upward, the opening of the flowerpot faces the outer wall or faces away from the outer wall, and the rainwater is not easy to enter the flowerpot through the opening of the flowerpot, so that the occurrence of plant root rot caused by ponding in the flowerpot is reduced, and the rainwater flows into the water receiving box along the outer side wall of the flowerpot, so that the water storage box can continuously store water;

when the opening of the flowerpot is not upward, the gauze can play a certain role in blocking the soil in the flowerpot, so that the soil in the flowerpot is not easy to spill out of the flowerpot;

after rain stop, the humidity in the air is reduced, so when the numerical value of the humidity sensor is reduced to a set numerical value, the humidity sensor triggers the controller, and the controller drives the rotating rod to rotate reversely by 90 degrees, so that the opening of the flowerpot is continuously upwards; when the soil in the flowerpot lacks water, the water in the water storage box can enter the flowerpot through the water absorption strip;

because the rainwater enters the flowerpot to enable the soil in the flowerpot to be moist and soft, when the flowerpot rotates along with the rotating rod, the soil which is not gripped by the roots of the plants in the flowerpot can slightly move, so that part of the soil in the flowerpot is loosened, the roots of the plants can obtain enough oxygen, and normal respiration of the roots is maintained.

Optionally, the water storage box is penetrated with an overflow port, and when the flowerpot rotates forward by 90 degrees, the overflow port faces upwards.

Through adopting above-mentioned technical scheme, when the opening of flowerpot up, excessive rainwater in the water storage box can follow the overflow mouth and flow to make the rainwater liquid level in the water storage box leave the clearance with the bottom of flowerpot, when the opening of flowerpot not up, in the rainwater can flow into the water storage box through the overflow mouth, and the rainwater in the water storage box can not flow out through the overflow mouth, and excessive rainwater can flow out through the water receiving mouth of water receiving box.

Optionally, the flowerpot is close to the one side of water receiving basin and runs through and offer the hole of permeating water, the hole of permeating water communicates with water receiving box.

Through adopting above-mentioned technical scheme, when the flowerpot corotation 90, if there is ponding in the flowerpot, ponding can flow into in the water receiving box through the hole that permeates water to further reduce the circumstances of ponding in the flowerpot.

Optionally, a water absorbing strip positioned in the water storage box is close to the overflow port.

Through adopting above-mentioned technical scheme, when the opening of flowerpot no longer upwards, when the rainwater passes through the overflow mouth and gets into in the retaining box, the rainwater can wet the strip that absorbs water, and the rainwater can get into in the flowerpot through the strip that absorbs water to make the soil in the flowerpot can keep moist state.

Optionally, be provided with a plurality of installation department on the dwang, the flowerpot is installed on the installation department, installation department and flowerpot one-to-one, the extension of installation department has the supporting seat, one side butt that the flowerpot was kept away from to the retaining box is on the supporting seat.

Through adopting above-mentioned technical scheme, when the opening of flowerpot upwards, the supporting seat can play stable supporting effect to flowerpot and retaining box, so the flowerpot can be installed on the dwang through installation department and supporting seat stability.

Optionally, the supporting seat is fixedly connected with inserted bar with one side of retaining box laminating, offer the joint hole that is used for supplying inserted bar joint on the retaining box.

Through adopting above-mentioned technical scheme, when the flowerpot was installed on the dwang, the inserted bar was pegged graft in the jack to make the retaining box can stably install on the supporting seat.

Optionally, the gauze has elasticity, and an elastic ring rope is arranged on a planting port of the gauze.

By adopting the technical scheme, the elastic ring rope can adapt to plants with different rhizome sizes, and can be spread open, so that soil is added into the flowerpot.

Optionally, the one end fixedly connected with driven gear of dwang, the controller is connected with positive and negative rotation motor, positive and negative rotation motor fixed mounting is on the outer wall body, the axis of rotation fixedly connected with drive gear of positive and negative rotation motor, drive gear and driven gear meshing.

By adopting the technical scheme, when the controller controls the forward and reverse rotation motor to forward or reverse rotation, the transmission gear drives the driven gear to rotate, so that the rotating rod rotates with the flowerpot.

Optionally, the driven gear has an outer diameter greater than an outer diameter of the drive gear.

By adopting the technical scheme, because the outer diameter of the driven gear is larger than that of the transmission gear, the rotating speed of the driven gear is smaller than that of the transmission gear, so that the rotating rod can stably bring the flowerpot to rotate.

In summary, the present application includes at least one of the following beneficial effects:

1. when water is accumulated in the flowerpot due to rain, the flowerpot can rotate along with the rotating rod until the opening of the flowerpot is not upward, and then the rainwater can flow into the water receiving box along the outer wall of the flowerpot, so that the rotting condition of plant roots caused by the accumulated water is reduced, and the rainwater can be recycled while the rainwater is not accumulated in the flowerpot;

2. the flowerpot is at pivoted in-process, and the soil in the flowerpot can be stopped to the gauze and the flowerpot is outwards poured out.

Drawings

Fig. 1 is a schematic view showing a structure in which a flowerpot according to the present embodiment is installed on an external wall;

FIG. 2 is an enlarged schematic view at A of FIG. 1;

fig. 3 is a schematic view showing the structure of the flowerpot according to the present embodiment;

fig. 4 is a schematic view showing a structure of the flowerpot rotated 90 ° in the forward direction according to the present embodiment;

fig. 5 is a schematic view showing the structure of the flowerpot and the water receiving box according to the embodiment;

FIG. 6 is an exploded view of the water receiving box according to the present embodiment;

fig. 7 is a schematic view showing the structure of a rotating lever according to the present embodiment;

fig. 8 is a schematic view showing a structure of a clamping hole of the water storage box according to the embodiment.

Reference numerals illustrate: 1. an outer wall; 2. a flower pot; 21. a water outlet hole; 22. gauze; 23. a planting port; 24. an elastic looped rope; 25. a water permeable hole; 26. a convex strip; 3. a rotating lever; 31. a mounting part; 311. a chute; 32. a support base; 321. a rod; 4. a support rod; 5. a forward and reverse rotation motor; 6. a transmission gear; 7. a driven gear; 8. a water storage box; 81. an overflow port; 82. an extension; 83. a clamping hole; 9. a water absorbing strip; 10. a water receiving box; 101. and a water receiving port.

Detailed Description

The application is described in further detail below with reference to fig. 1-8.

The embodiment of the application discloses a wall structure of a house building. Referring to fig. 1, the wall structure includes an outer wall 1 and a flowerpot 2 installed on the outer wall 1, and plants are planted in the flowerpot 2. The outer wall body 1 is provided with a control component for controlling the rotation of the flowerpot 2, the control component comprises a rotating rod 3, the rotating rod 3 is rotatably arranged on the outer wall body 1, and a plurality of rotating rods 3 are uniformly distributed along the height direction of the outer wall body 1. Flowerpot 2 fixed mounting is on dwang 3, and flowerpot 2 has a plurality of along the length direction equipartition of dwang 3.

Referring to fig. 1 and 2, a support bar 4 for supporting a rotation bar 3 is fixedly connected to an outer wall 1, and both ends of one rotation bar 3 are rotatably installed on the two support bars 4, respectively. The control assembly further comprises a controller (not shown in the figure) for controlling the rotation of the rotating rod 3, the controller is arranged on the outer wall body 1, the controller is connected with a forward and reverse rotation motor 5, and the forward and reverse rotation motor 5 is also arranged on the outer wall body 1. The rotation shaft of the forward and reverse rotation motor 5 is fixedly connected with a transmission gear 6, one end of the rotation rod 3, which is close to the forward and reverse rotation motor 5, is fixedly connected with a driven gear 7, and the driven gear 7 is meshed with the transmission gear 6. When the forward and reverse rotation motor 5 rotates, the transmission gear 6 drives the driven gear 7 to rotate, so that the rotating rod 3 drives the flowerpot 2 to rotate.

Referring to fig. 2, the outer diameter of the transmission gear 6 is smaller than the outer diameter of the driven gear 7, and the outer diameter of the driven gear 7 of the present embodiment is twice the outer diameter of the transmission gear 6. So that the rotation speed of the transmission gear 6 is twice that of the driven gear 7 when the forward and reverse rotation motor 5 drives the transmission gear 6 to rotate. So that the rotating rod 3 can smoothly rotate with the flowerpot 2 when the rotating rod 3 rotates.

Referring to fig. 3, the bottom of the flowerpot 2 is provided with a water outlet 21, and the inner wall of the flowerpot 2 is coated with geotextile, which can filter water in the flowerpot 2, thereby reducing the loss of soil in the flowerpot 2. The bottom of the flowerpot 2 is connected with a water storage box 8, and the water storage box 8 is communicated with the flowerpot 2 through a water outlet 21. After the rainwater flows into the flowerpot 2, the excessive rainwater can enter the water storage box 8.

Referring to fig. 3, an overflow port 81 is formed in the outer wall of the water storage box 8, and the overflow port 81 is close to the flowerpot 2. A water absorbing strip 9 is connected between the flowerpot 2 and the water storage box 8, and the water absorbing strip 9 positioned in the water storage box 8 is close to the overflow port 81. The water absorbing strip 9 is capable of delivering water into the pot 2 when the opening of the pot 2 is up. The absorbent strip 9 may be a tampon or a sponge strip.

Referring to fig. 2 and 4, the controller is connected with a humidity sensor (not shown) installed on the outer wall 1. Two values of higher humidity and lower humidity are set on the humidity sensor. After a period of raining, the humidity sensor can reach a higher numerical value of humidity, and at the moment, the humidity sensor triggers the controller, and the controller drives the rotating shaft of the forward and backward rotating motor to rotate forward by 90 degrees. So that the opening of the flowerpot 2 is not upward any more and rainwater can not enter the flowerpot 2 through the opening of the flowerpot 2.

Referring to fig. 2 and 4, after a period of rain stop, the humidity sensor can be lowered to a lower humidity value, at which time the humidity sensor triggers the controller, which drives the rotation shaft of the forward and reverse motor 5 to rotate reversely by 90 °. So that the opening of the flowerpot 2 continues upward. During the rotation of the flowerpot 2, part of the soil in the flowerpot 2 can move, so that the roots of the plants can obtain more oxygen.

Referring to fig. 4 and 5, when the flowerpot 2 rotates along with the rotation rod 3, in order to prevent soil in the flowerpot 2 from being easily spilled, an opening of the flowerpot 2 is covered with a gauze 22 having elasticity, and a planting hole 23 for allowing plants to extend out of the flowerpot 2 is formed in the gauze 22. An annular elastic ring rope 24 is arranged on the planting hole 23. The plants planted in the flowerpot 2 are rhizome plants such as bougainvillea spectabilis, cymbidium, and the like.

When plants are planted, soil is first loaded into the flowerpot 2, and gauze 22 is installed on the flowerpot 2. The elastic ring rope 24 is then spread to insert the plant species into the soil of the flowerpot 2. The elastic loop cord 24 may be attached to the rhizomes of the plant so that the planting hole 23 of the gauze 22 can accommodate the growth of the plant. If soil is required to be added, the elastic ring rope 24 can be stretched so that the soil can be smoothly added into the flowerpot 2.

Referring to fig. 5 and 6, the water storage box 8 includes an extension 82, and the extension 82 can increase the volume of the water storage box 8 to accommodate rainwater. The extension 82 is fixedly connected with a water receiving box 10 near one side of the flowerpot 2, and the water receiving box 10 and the water storage box 8 are communicated with each other. A gap is reserved between one side of the water receiving box 10 close to the flowerpot 2 and the outer side wall of the flowerpot 2, and a water receiving port 101 for receiving water is formed in one side of the water receiving box 10 close to the flowerpot 2.

Referring to fig. 4, when the flowerpot 2 is rotated 90 ° forward, the opening of the flowerpot 2 faces away from the outer wall 1, and the water receiving box 10 is located below the flowerpot 2, rainwater striking the outer side wall of the flowerpot 2 can flow into the water receiving box 10 along the outer wall of the flowerpot 2, so that the water storage box 8 can also store water. When the water storage box 8 rotates along with the flowerpot 2, water pages in the water storage box 8 can enter the water receiving box 10.

Referring to fig. 3, the flowerpot 2 has a water permeable hole 25 penetrating through an outer sidewall of the water receiving box 10, and the water receiving box 10 communicates with the water permeable hole 25. When the opening of the flowerpot 2 faces away from the outer wall 1, the accumulated water in the flowerpot 2 can flow into the water receiving box 10 through the water permeable holes 25, so that the accumulated water in the flowerpot 2 is further reduced.

Referring to fig. 3 and 5, when the opening of the flowerpot 2 faces away from the outer wall 1, the overflow port 81 faces upward. Rainwater can enter the water storage box 8 through the overflow port 81, and the rainwater can wet the water absorbing strips 9 close to the overflow port 81, and the wet water absorbing strips 9 keep the soil in the flowerpot 2 in a wet state.

Referring to fig. 7, the rotation lever 3 is provided with a plurality of mounting portions 31 for mounting the flower pot 2, and the mounting portions 31 are in one-to-one correspondence with the flower pot 2. The mounting portion 31 surrounds the flowerpot 2, and the water receiving box 10 is also located in the mounting portion 31. The outer wall of the flowerpot 2 is extended with a convex strip 26, and the mounting portion 31 is provided with a chute 311 for sliding the convex strip 26 in. The protruding strips 26 are engaged with the sliding grooves 311, so that the flowerpot 2 is mounted on the mounting portion 31.

Referring to fig. 7 and 8, the mounting portion 31 extends with a support base 32, and a side of the water storage box 8 remote from the flowerpot 2 abuts against the support base 32. One side of the supporting seat 32, which is attached to the water storage box 8, is fixedly connected with a plug rod 321, and the water storage box 8 is provided with a clamping hole 83 for clamping the plug rod 321. When the flowerpot 2 is mounted in the mounting portion 31, the water storage box 8 is clamped on the insert rod 321, so that the flowerpot 2 can be mounted on the rotating rod 3 more firmly.

The implementation principle of the wall structure of the house building provided by the embodiment of the application is as follows:

when raining, rainwater enters the flowerpot 2, when the rainwater in the flowerpot 2 enters the water storage box 8, after the humidity value of the humidity sensor rises to a set value, the controller controls the rotating rod 3 to rotate forwards by 90 degrees to be triggered, so that the opening of the flowerpot 2 is not upward any more, the rainwater can not enter the water storage box 8 through the flowerpot 2 any more, the water accumulation condition of the flowerpot 2 is reduced, and the rotting condition of plant roots due to the water accumulation is improved;

and in rainwater can flow into water receiving box 10 along the lateral wall of flowerpot 2, because water receiving box 10 and retaining box 8 communicate each other, so retaining box 8 can continue retaining to make rainwater can obtain more abundant utilization, the plant on the outer wall can more abundant utilization rainwater, can save water resource more.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (5)

1. The utility model provides a building's wall structure, includes outer wall body (1), install flowerpot (2), its characterized in that on outer wall body (1): the opening of the flowerpot (2) is coated with gauze (22), and a planting opening (23) for a plant to extend out of the flowerpot (2) is formed in the gauze (22);

the flowerpot is characterized in that a water outlet hole (21) is formed in the bottom of the flowerpot (2), a water storage box (8) is connected to the bottom of the flowerpot (2), the water storage box (8) is communicated with the bottom of the flowerpot (2), and a water absorption strip (9) is connected between the water storage box (8) and the flowerpot (2);

the flowerpot comprises an outer wall body (1), wherein a control assembly for controlling the rotation of the flowerpot body (2) is arranged on the outer wall body (1), the control assembly comprises a rotating rod (3) rotatably arranged on the outer wall body (1) and a controller for controlling the rotating rod (3) to rotate, the controller is arranged on the outer wall body (1), a plurality of flowerpots (2) are uniformly distributed along the length direction of the rotating rod (3), and a plurality of rotating rods (3) are arranged along the height direction of the outer wall body (1);

the controller is connected with a humidity sensor, the humidity sensor is arranged on the outer wall body (1), and the humidity sensor triggers the controller to drive the rotating rod (3) to rotate forward by 90 degrees or rotate reversely by 90 degrees;

the water storage box (8) comprises an extension part (82), one side of the extension part (82) facing the flowerpot (2) is connected with a water receiving box (10), the water receiving box (10) is communicated with the water storage box (8), a water receiving port (101) is formed in one side, close to the flowerpot (2), of the water receiving box (10), a gap is reserved between the water receiving box (10) and the outer side wall of the flowerpot (2), and when the flowerpot (2) rotates forwards by 90 degrees, the water receiving box (10) is located below the flowerpot (2);

the water storage box (8) is penetrated with an overflow port (81), and when the flowerpot (2) rotates forward by 90 degrees, the overflow port (81) faces upwards;

a water permeable hole (25) is formed in one side, close to the water receiving box (10), of the flowerpot (2) in a penetrating mode, and the water permeable hole (25) is communicated with the water receiving box (10);

the water absorbing strip (9) positioned in the water storage box (8) is close to the overflow port (81);

be provided with a plurality of installation department (31) on dwang (3), flowerpot (2) are installed on installation department (31), installation department (31) and flowerpot (2) one-to-one, the extension of installation department (31) has supporting seat (32), one side butt on supporting seat (32) that flowerpot (2) were kept away from to retaining box (8).

2. A wall structure of a building construction according to claim 1, wherein: one side of supporting seat (32) and laminating of retaining box (8) fixedly connected with inserted bar (321), set up on retaining box (8) and be used for supplying joint hole (83) of inserted bar (321) joint.

3. A wall structure of a building construction according to claim 2, characterized in that: the gauze (22) has elasticity, and an elastic ring rope (24) is arranged on a planting port (23) of the gauze (22).

4. A wall structure of a building construction according to claim 1, wherein: one end fixedly connected with driven gear (7) of dwang (3), the controller is connected with positive and negative motor (5), positive and negative motor (5) fixed mounting is on outer wall body (1), the axis of rotation fixedly connected with drive gear (6) of positive and negative motor (5), drive gear (6) and driven gear (7) meshing.

5. A wall structure of a building construction according to claim 4, wherein: the outer diameter of the driven gear (7) is larger than that of the transmission gear (6).