CN113112905A

CN113112905A - County and country level territory space planning optimization method and system

Info

Publication number: CN113112905A
Application number: CN202110410874.4A
Authority: CN
Inventors: 刘润乾; 张世平; 何毅; 蔡志伟; 张君; 班高尚
Original assignee: Individual
Current assignee: Beijing Baixin Blueprint Technology Co ltd
Priority date: 2021-04-16
Filing date: 2021-04-16
Publication date: 2021-07-13
Anticipated expiration: 2041-04-16
Also published as: CN113112905B

Abstract

The invention provides a county-country-level territory space planning optimization method and system, relates to the technical field of territory space planning, and solves the problem that simulation of solar irradiation cannot be realized through structural improvement so as to realize reasonable control adjustment of building spacing; the rotary air injection cleaning of dust of an irradiation lamp and a building model can not be realized while the illumination simulation is realized. A county and country level territory space planning optimization method and system comprises a table body; install the building model on the table body, and still install on the table body and shine the structure to shine and structural the installing clean structure. Through the arrangement of the protection plate, the protection plate is connected with the sliding hole in a sliding mode and is located above the sliding rod, and the protection plate forms a collision protection structure of the sliding rod, so that the protection of the sliding rod can be realized; the sliding hole is arc poroid structure, and the internal diameter in sliding hole is greater than the external diameter of guard plate to do not influence the normal slip of sliding block after the guard plate slightly warp.

Description

County and country level territory space planning optimization method and system

Technical Field

The invention belongs to the technical field of territorial space planning, and particularly relates to a county-country territorial space planning optimization method and system.

Background

The urbanization speed of China is faster and faster, the urbanization rate in the current year is only 17.9 percent, and the urbanization rate reaches 59.6 percent by 2018; with the continuous increase of urban space land, in the process of space planning, establishment and implementation, urban buildings can obtain less and less homeland resources, and the optimization of a homeland space development pattern is urgent.

As in application No.: CN202011130974.3, the invention provides a territorial space planning method, which comprises the following steps: firstly, collecting land and landform type resource data, wherein the land and landform type resource data comprise plains, rivers, forests, mountains and oceans, and dividing an area to be classified into a plurality of different sets according to the landform type; secondly, performing primary data analysis including soil, rocks, vegetation, aquatic products and underground water veins according to the national landform type resource data, and dividing the data into a plurality of different subsets according to the primary data analysis; thirdly, firstly, collecting and acquiring original planning data information, and then establishing a territorial space planning data set; the space planning data set comprises a city planning data set, a country planning data set, a forestry planning data set, an agricultural planning data set, a grass planning data set, a marine planning data set and the like; fourth, the data is processed.

The territorial space planning method and the display device similar to the application have the following defects at present:

one is that the existing device has lower practicability, and can not realize the simulation of solar irradiation through structural improvement so as to realize the reasonable control adjustment of the inter-floor distance; moreover, the existing device can not realize illumination simulation and simultaneously realize rotary air injection cleaning of dust of the irradiation lamp and the building model.

Therefore, in view of the above, research and improvement are performed on the existing structure and deficiency, and a county-country-level homeland space planning optimization method and system are provided, so as to achieve the purpose of having more practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a county and county level territory space planning optimization method and system, aiming at solving the problems that the existing device is low in practicability and cannot realize the simulation of solar irradiation through structural improvement so as to realize reasonable control adjustment of building spacing; moreover, the prior device can not realize illumination simulation and simultaneously realize rotary air injection cleaning of dust of the irradiation lamp and the building model.

The purpose and the effect of the county-country-level territory space planning optimization method and the county-country-level territory space planning optimization system are achieved by the following specific technical means:

a county and country level territory space planning optimization method and system comprises a table body; the table body is provided with a building model, the table body is also provided with an irradiation structure, and the irradiation structure is provided with a cleaning structure; the building model comprises an extrusion block, and the extrusion block is welded on the base body; the cleaning structure comprises a telescopic gas cylinder and a connecting pipe, the telescopic gas cylinder is fixedly connected to the sliding block, and the telescopic gas cylinder is connected with the connecting pipe; the head end of the telescopic gas cylinder is in contact with the top end face of the extrusion block, and the top end face of the extrusion block is of an inclined structure.

Furthermore, the irradiation structure comprises a base body, sliding rods, a sliding block, an irradiation lamp, a threaded rod and a driving motor, wherein the base body is welded on the base body, and the base body is welded with the two sliding rods; the two sliding rods are connected with a sliding block in a sliding way, and the sliding block is provided with a radiation lamp; the threaded rod is rotatably connected to the seat body and is in threaded connection with the sliding block; the driving motor is fixedly connected to the base body, the rotating shaft of the driving motor is connected with the threaded rod, and the driving motor and the threaded rod jointly form a threaded driving structure of the sliding block and the irradiation lamp.

Furthermore, the building model also comprises a control box, a microprocessor and a 4G receiving terminal, wherein the control box is arranged on the base body, the microprocessor and the 4G receiving terminal are arranged in the control box, and the microprocessor is electrically connected with the 4G receiving terminal; the microprocessor is electrically connected with the irradiation lamp and the driving motor, and is also electrically connected with an external power supply.

Furthermore, the irradiation structure further comprises a contact switch, the contact switch is installed on the base body, and the contact switch is electrically connected with the microprocessor.

Furthermore, the irradiation structure also comprises two sliding holes and two protection plates, wherein the two sliding holes are symmetrically formed in the sliding block; the number of the protection plates is two, and the two protection plates are symmetrically welded on the seat body; the protection plate is connected with the sliding hole in a sliding mode, the protection plate is located above the sliding rod, and the protection plate forms a collision protection structure of the sliding rod.

Furthermore, the sliding holes are all arc-shaped hole structures, and the inner diameter of each sliding hole is larger than the outer diameter of the protection plate.

Furthermore, the cleaning structure also comprises a rotating seat, a spray pipe and a spray hole, wherein the rotating seat is welded on the sliding block, and the rotating seat is rotatably connected with the spray pipe; the spray pipe is of a cylindrical tubular structure, the spray pipes are provided with spray holes in an annular array shape, and the spray holes in the annular array shape jointly form a diffusion type air injection structure of the spray pipe.

Furthermore, the cleaning structure also comprises a tooth row and a gear, wherein the tooth row is fixedly connected to the seat body through a bolt; the gear is arranged on the spray pipe, the spray pipe is positioned at the right side of the irradiation lamp, and the spray pipe is also positioned above the building model; the gear row is meshed with the gear, and the gear row and the gear jointly form a spray pipe rotating structure.

The invention discloses a county-country-level territory space planning optimization method and system, which are characterized by comprising the following steps of:

1) and the 4G receiving terminal receives the signal, and then the 4G receiving terminal transmits the signal to the microprocessor.

2) And the microprocessor controls the illumination of the irradiation lamp.

3) The microprocessor also controls the driving motor to rotate, and the sliding block can move rightwards through the rotation of the driving motor, so that the simulation of sunlight irradiation can be realized through the displacement of the irradiation lamp.

4) And when the sliding block moves rightwards for 1.5m, the sliding block is contacted with the contact switch, and the contact switch transmits a signal to the microprocessor.

5) And the microprocessor controls the driving motor to reversely rotate, and the sliding block can move leftwards through the reverse rotation of the driving motor.

6) And after the 4G receiving terminal receives the closing signal, the 4G receiving terminal transmits the signal to the microprocessor, and the microprocessor controls the irradiation lamp to be closed and the driving motor to stop working.

Compared with the prior art, the invention has the following beneficial effects:

through the arrangement of the protection plate, the protection plate is connected with the sliding hole in a sliding mode and is located above the sliding rod, and the protection plate forms a collision protection structure of the sliding rod, so that the protection of the sliding rod can be realized; the sliding hole is arc poroid structure, and the internal diameter in sliding hole is greater than the external diameter of guard plate to do not influence the normal slip of sliding block after the guard plate slightly warp.

Through the matching arrangement of the irradiation structure and the cleaning structure, firstly, the telescopic gas cylinder is fixedly connected to the sliding block and is connected with a connecting pipe; the head end of the telescopic gas cylinder is in contact with the top end face of the extrusion block, and the top end face of the extrusion block is of an inclined structure, so that when the telescopic gas cylinder moves along with the sliding block, extrusion and air injection at the connecting pipe can be realized through extrusion of the extrusion block; the rotating seat is welded on the sliding block, and the rotating seat is rotatably connected with a spray pipe; the spray pipe is of a cylindrical tubular structure, spray holes are formed in the spray pipe in an annular array shape, and the spray holes formed in the annular array shape jointly form a diffusion type air injection structure of the spray pipe; secondly, the gear row is fixedly connected to the seat body through a bolt; the gear is arranged on the spray pipe, the spray pipe is positioned at the right side of the irradiation lamp, and the spray pipe is also positioned above the building model; tooth row and gear engagement, and tooth row and gear have constituteed spray tube rotating-structure jointly to can realize the jet-propelled and the rotation of spray tube through the meshing transmission of tooth row and gear when the spray tube follows the sliding block and removes, and then realized that the jet-propelled of illuminating lamp and architectural model is clean.

Drawings

Fig. 1 is a schematic axial view of the present invention.

Fig. 2 is an enlarged schematic view of fig. 1 at a.

Fig. 3 is a schematic axial view of the present invention in another direction of fig. 1.

Fig. 4 is an enlarged view of the structure of fig. 3B according to the present invention.

Fig. 5 is an axial view structure schematic diagram of the invention with the table body and the building model removed.

Fig. 6 is an enlarged view of the structure of fig. 5C according to the present invention.

Fig. 7 is a right view structural schematic diagram of the illumination structure of the present invention.

Fig. 8 is an enlarged view of fig. 7D according to the present invention.

Fig. 9 is a schematic diagram of the system structure of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a table body; 2. a building model; 3. illuminating the structure; 301. a base body; 302. a slide bar; 303. a slider; 30301. a slide hole; 304. illuminating a lamp; 305. a threaded rod; 306. a drive motor; 307. a control box; 308. a microprocessor; 309. a contact switch; 310. a 4G receiving terminal; 311. a protection plate; 312. extruding the block; 4. cleaning the structure; 401. a telescopic gas cylinder; 402. a connecting pipe; 403. a rotating seat; 404. a nozzle; 405. spraying a hole; 406. a tooth row; 407. a gear.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 9:

the invention provides a county and county level territory space planning optimization method and system, comprising a table body 1; the table body 1 is provided with a building model 2, the table body 1 is also provided with an irradiation structure 3, and the irradiation structure 3 is provided with a cleaning structure 4; referring to fig. 5, the construction model 2 includes an extrusion block 312, and the extrusion block 312 is welded to the base 301; the cleaning structure 4 comprises a telescopic gas cylinder 401 and a connecting pipe 402, the telescopic gas cylinder 401 is fixedly connected to the sliding block 303, and the telescopic gas cylinder 401 is connected with the connecting pipe 402; the head end of the telescopic gas cylinder 401 is in contact with the top end face of the extrusion block 312, and the top end face of the extrusion block 312 is of an inclined structure, so that when the telescopic gas cylinder 401 moves along with the sliding block 303, extrusion and gas injection at the connecting pipe 402 can be realized through extrusion of the extrusion block 312.

Referring to fig. 3 and 4, the irradiation structure 3 includes a base 301, a sliding rod 302, a sliding block 303, an irradiation lamp 304, a threaded rod 305, and a driving motor 306, wherein the base 301 is welded on the base 301, and two sliding rods 302 are welded on the base 301; a sliding block 303 is connected on the two sliding rods 302 in a sliding manner, and a radiation lamp 304 is arranged on the sliding block 303; the threaded rod 305 is rotatably connected to the base body 301, and the threaded rod 305 is in threaded connection with the sliding block 303; the driving motor 306 is fixedly connected to the base 301, a rotating shaft of the driving motor 306 is connected to the threaded rod 305, and the driving motor 306 and the threaded rod 305 jointly form a threaded driving structure of the sliding block 303 and the irradiation lamp 304.

Referring to fig. 9, the construction model 2 further includes a control box 307, a microprocessor 308 and a 4G receiving terminal 310, the control box 307 is installed on the base 301, the microprocessor 308 and the 4G receiving terminal 310 are installed in the control box 307, and the microprocessor 308 and the 4G receiving terminal 310 are electrically connected; the microprocessor 308 is electrically connected to the lamp 304 and the driving motor 306, and the microprocessor 308 is further electrically connected to an external power source.

Referring to fig. 4 and 9, the irradiation structure 3 further includes a contact switch 309, the contact switch 309 is mounted on the base 301, and the contact switch 309 is electrically connected to the microprocessor 308.

Referring to fig. 5, the irradiation structure 3 further includes two sliding holes 30301 and a protection plate 311, the two sliding holes 30301 are provided, and the two sliding holes 30301 are symmetrically provided on the sliding block 303; two protection plates 311 are arranged, and the two protection plates 311 are symmetrically welded on the seat body 301; the protection plate 311 is connected with the sliding hole 30301 in a sliding manner, the protection plate 311 is located above the sliding rod 302, and the protection plate 311 forms a collision protection structure of the sliding rod 302, so that protection of the sliding rod 302 can be realized.

Referring to fig. 8, the sliding holes 30301 are each arc-shaped hole structure, and the inner diameter of the sliding hole 30301 is larger than the outer diameter of the protection plate 311, so that the normal sliding of the sliding block 303 is not affected when the protection plate 311 is slightly deformed.

Referring to fig. 5 and 6, the cleaning structure 4 further includes a rotating base 403, a nozzle 404 and a nozzle 405, the rotating base 403 is welded on the sliding block 303, and the nozzle 404 is rotatably connected to the rotating base 403; the nozzle 404 is a cylindrical tubular structure, and the nozzle 404 is provided with nozzle holes 405 in an annular array, and the nozzle holes 405 in the annular array form a diffusion type air injection structure of the nozzle 404.

Referring to fig. 6, the cleaning structure 4 further includes a tooth row 406 and a gear 407, the tooth row 406 is fixedly connected to the holder body 301 by bolts; the gear 407 is mounted on the nozzle 404 with the nozzle 404 located at the right position of the lamp 304 and the nozzle 404 also located at the upper position of the construction model 2; the teeth 406 are engaged with the gear 407, and the teeth 406 and the gear 407 jointly form a rotating structure of the nozzle 404, so that when the nozzle 404 moves along with the sliding block 303, the air injection and the rotation of the nozzle 404 can be realized through the engagement transmission of the teeth 406 and the gear 407, and further, the air injection cleaning of the irradiation lamp 304 and the architectural model 2 is realized.

1) the 4G receiving terminal 310 receives the signal, and then the 4G receiving terminal 310 transmits the signal to the microprocessor 308.

2) And the microprocessor 308 controls the illumination of the lamp 304.

3) The microprocessor 308 also controls the driving motor 306 to rotate, and the sliding block 303 can move rightwards through the rotation of the driving motor 306, so that the simulated sunlight irradiation can be realized through the displacement of the irradiation lamp 304.

4) When the slider 303 moves to the right by 1.5m, the slider 303 comes into contact with the contact switch 309, and the contact switch 309 transmits a signal to the microprocessor 308.

5) The microprocessor 308 controls the driving motor 306 to rotate in reverse, and the slider 303 can be moved leftward by the reverse rotation of the driving motor 306.

6) After the 4G receiving terminal 310 receives the turn-off signal, the 4G receiving terminal 310 transmits the signal to the microprocessor 308, and the microprocessor 308 controls the lamp 304 to turn off and the driving motor 306 to stop working.

The specific use mode and function of the embodiment are as follows:

when the sliding block 303 is used, firstly, the 4G receiving terminal 310 receives signals, then the 4G receiving terminal 310 transmits the signals to the microprocessor 308, the microprocessor 308 controls the irradiation lamp 304 to be turned on, and also controls the driving motor 306 to rotate, the sliding block 303 can move rightwards through the rotation of the driving motor 306, after the sliding block 303 is contacted with the contact switch 309, the contact switch 309 transmits the signals to the microprocessor 308, and then the microprocessor 308 controls the driving motor 306 to rotate reversely, so that the reverse movement of the sliding block 303 is realized, and the simulated sunlight irradiation is realized;

in the using process, firstly, the protection plate 311 is connected with the sliding hole 30301 in a sliding manner, the protection plate 311 is positioned above the sliding rod 302, and the protection plate 311 forms a collision protection structure of the sliding rod 302, so that the protection of the sliding rod 302 can be realized; the sliding holes 30301 are all arc-shaped hole structures, and the inner diameter of the sliding holes 30301 is larger than the outer diameter of the protection plate 311, so that the normal sliding of the sliding block 303 is not influenced after the protection plate 311 is slightly deformed; secondly, the telescopic gas cylinder 401 is fixedly connected to the sliding block 303, and the telescopic gas cylinder 401 is connected with a connecting pipe 402; the head end of the telescopic gas cylinder 401 is in contact with the top end face of the extrusion block 312, and the top end face of the extrusion block 312 is of an inclined structure, so that when the telescopic gas cylinder 401 moves along with the sliding block 303, extrusion and gas injection at the connecting pipe 402 can be realized through extrusion of the extrusion block 312; the rotating seat 403 is welded on the sliding block 303, and the rotating seat 403 is rotatably connected with a spray pipe 404; the spray pipe 404 is a cylindrical tubular structure, spray holes 405 are formed in the spray pipe 404 in an annular array shape, and the spray holes 405 formed in the annular array shape jointly form a diffusion type air injection structure of the spray pipe 404; thirdly, the gear row 406 is fixedly connected to the seat body 301 through bolts; the gear 407 is mounted on the nozzle 404 with the nozzle 404 located at the right position of the lamp 304 and the nozzle 404 also located at the upper position of the construction model 2; the teeth 406 are engaged with the gear 407, and the teeth 406 and the gear 407 jointly form a rotating structure of the nozzle 404, so that when the nozzle 404 moves along with the sliding block 303, the air injection and the rotation of the nozzle 404 can be realized through the engagement transmission of the teeth 406 and the gear 407, and further, the air injection cleaning of the irradiation lamp 304 and the architectural model 2 is realized.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. A county and country level territory space planning optimization method and system are characterized in that: a county and country level territory space planning optimization device comprises a table body (1); the table body (1) is provided with a building model (2), the table body (1) is also provided with an irradiation structure (3), and the irradiation structure (3) is provided with a cleaning structure (4); the building model (2) comprises an extrusion block (312), and the extrusion block (312) is welded on the base body (301); the cleaning structure (4) comprises a telescopic gas cylinder (401) and a connecting pipe (402), the telescopic gas cylinder (401) is fixedly connected to the sliding block (303), and the telescopic gas cylinder (401) is connected with the connecting pipe (402); the head end of the telescopic gas cylinder (401) is in contact with the top end face of the extrusion block (312), and the top end face of the extrusion block (312) is of an inclined structure.

2. The county-level territory space planning optimization device of claim 1, wherein: the irradiation structure (3) comprises a base body (301), sliding rods (302), sliding blocks (303), irradiation lamps (304), a threaded rod (305) and a driving motor (306), wherein the base body (301) is welded on the base body (301), and the base body (301) is welded with the two sliding rods (302); a sliding block (303) is connected on the two sliding rods (302) in a sliding way, and a radiation lamp (304) is arranged on the sliding block (303); the threaded rod (305) is rotatably connected to the base body (301), and the threaded rod (305) is in threaded connection with the sliding block (303); the driving motor (306) is fixedly connected to the base body (301), a rotating shaft of the driving motor (306) is connected with the threaded rod (305), and the driving motor (306) and the threaded rod (305) jointly form a threaded driving structure of the sliding block (303) and the irradiation lamp (304).

3. The county-level territory space planning optimization device of claim 1, wherein: the building model (2) further comprises a control box (307), a microprocessor (308) and a 4G receiving terminal (310), wherein the control box (307) is installed on the base body (301), the microprocessor (308) and the 4G receiving terminal (310) are installed in the control box (307), and the microprocessor (308) is electrically connected with the 4G receiving terminal (310); the microprocessor (308) is electrically connected with the irradiation lamp (304) and the driving motor (306), and the microprocessor (308) is also electrically connected with an external power supply.

4. The county-level territory space planning optimization device of claim 1, wherein: the irradiation structure (3) further comprises a contact switch (309), the contact switch (309) is installed on the base body (301), and the contact switch (309) is electrically connected with the microprocessor (308).

5. The county-level territory space planning optimization device of claim 1, wherein: the irradiation structure (3) further comprises two sliding holes (30301) and a protection plate (311), the two sliding holes (30301) are arranged, and the two sliding holes (30301) are symmetrically arranged on the sliding block (303); the number of the protection plates (311) is two, and the two protection plates (311) are symmetrically welded on the base body (301); protection plate (311) and sliding hole (30301) sliding connection, and protection plate (311) are located the top position of slide bar (302) to protection plate (311) have constituteed the protection structure that collides with of slide bar (302).

6. The county-level territory space planning optimization device of claim 5, wherein: the sliding hole (30301) is of an arc-shaped hole structure, and the inner diameter of the sliding hole (30301) is larger than the outer diameter of the protection plate (311).

7. The county-level territory space planning optimization device of claim 1, wherein: the cleaning structure (4) further comprises a rotating seat (403), a spray pipe (404) and a spray hole (405), the rotating seat (403) is welded on the sliding block (303), and the rotating seat (403) is rotatably connected with the spray pipe (404); the spray pipe (404) is of a cylindrical tubular structure, the spray pipe (404) is provided with spray holes (405) in an annular array shape, and the spray holes (405) in the annular array shape jointly form a diffusion type air injection structure of the spray pipe (404).

8. The county-level territory space planning optimization device of claim 1, wherein: the cleaning structure (4) further comprises a tooth row (406) and a gear (407), wherein the tooth row (406) is fixedly connected to the base body (301) through a bolt; the gear (407) is installed on the spray pipe (404), the spray pipe (404) is positioned at the right side position of the irradiation lamp (304), and the spray pipe (404) is also positioned at the upper position of the building model (2); the tooth row (406) is meshed with the gear (407), and the tooth row (406) and the gear (407) jointly form a rotating structure of the spray pipe (404).

9. The county and county level territory space planning optimization method and system of any one of claims 1 to 8, comprising the steps of:

1) the 4G receiving terminal (310) receives the signal, and then the 4G receiving terminal (310) transmits the signal to the microprocessor (308);

2) the microprocessor (308) controls the illumination of the illumination lamp (304);

3) the microprocessor (308) also controls the driving motor (306) to rotate, and the sliding block 303 can move rightwards through the rotation of the driving motor 306, so that the simulated sunlight irradiation can be realized through the displacement of the irradiation lamp (304);

4) when the sliding block (303) moves rightwards for 1.5m, the sliding block (303) is contacted with a contact switch (309), and the contact switch (309) transmits a signal to the microprocessor (308);

5) the microprocessor (308) controls the driving motor (306) to rotate reversely, and the sliding block (303) can move leftwards through the reverse rotation of the driving motor (306);

6) and after the 4G receiving terminal (310) receives the closing signal, the 4G receiving terminal (310) transmits the signal to the microprocessor (308), and the microprocessor (308) controls the irradiation lamp (304) to be closed and the driving motor (306) to stop working.