CN116642243A

CN116642243A - Anti-condensation control method and system for underground garage

Info

Publication number: CN116642243A
Application number: CN202310518938.1A
Authority: CN
Inventors: 范晨阳; 冯仰歌; 王礼正; 李涛; 李宏俊
Original assignee: Nanjing Changge Technology Development Co ltd
Current assignee: Nanjing Changge Technology Development Co ltd
Priority date: 2023-05-10
Filing date: 2023-05-10
Publication date: 2023-08-25
Anticipated expiration: 2043-05-10
Also published as: CN116642243B

Abstract

The invention provides an underground garage anti-condensation control method and system, which are characterized by acquiring a ground garage plane image, determining a plurality of ground garage side lines, determining middle points of the ground garage side lines, generating a first central line perpendicular to the ground garage side lines, dividing regions to obtain a plurality of ground garage subareas, setting at least one dehumidification device and detection devices, acquiring subarea central points and access points, calculating dividing distances, determining optimal ground garage entrances and exits, generating subarea sets corresponding to each ground garage entrance and exit, acquiring corresponding current humidity according to the detection devices, determining a first ground garage subarea and determining adjacent second ground garage subareas if the current humidity is greater than the preset humidity, operating the dehumidification devices in the first ground garage subareas according to first power, operating the dehumidification devices in the second ground garage subareas according to second power, acquiring shutter door units corresponding to the first subarea sets as first shutter door units, and controlling the working mode to be switched from a normally open mode to an open mode.

Description

Anti-condensation control method and system for underground garage

Technical Field

The invention relates to the technical field of data processing, in particular to an anti-condensation control method and system for an underground garage.

Background

When the air temperature in the underground garage is higher than the wall surface temperature (the wall surface temperature is lower than the dew point) and the relative humidity of indoor air is high, water vapor can form condensation on the smoother wall surface, and the dew point can be condensed into water drops. The phenomenon is particularly prominent in the inner wall and the ground of the underground garage, particularly when the underground garage is not ventilated smoothly, and the inner corner part of the underground garage, which is in direct contact with the soil outside the underground garage, can lead to the slip of the mould-growing ground on the inner wall surface to affect the use if the phenomenon exists for a long time.

In the prior art, the garage often needs a plurality of dehumidifiers to work simultaneously to meet the dehumidification requirement, but the energy consumption of the dehumidifier is often higher, the cost caused by long-time operation can be very high, and especially in some large-scale underground garages, the dehumidifier often works all the time to keep the garage dry, so that the use cost is extremely high, and the energy conservation is also unfavorable.

Therefore, how to combine the sensing data of different areas of the underground garage and regulate and control the working states of the dehumidifiers in corresponding numbers of different areas in real time, and the reduction of the operation cost becomes a problem to be solved urgently.

Disclosure of Invention

The embodiment of the invention provides an anti-condensation control method and system for an underground garage, which are used for dividing the garage into areas, adjusting the working states of a corresponding number of dehumidifiers in an abnormal area by combining monitoring data of different areas, and adjusting the working states of corresponding rolling shutter door units by combining the area data.

In a first aspect of the embodiment of the present invention, there is provided an anti-condensation control method for an underground garage, including:

acquiring a ground library plane image, determining a plurality of ground library side lines according to the ground library plane image, determining the middle point of each ground library side line, generating a first central line perpendicular to the ground library side lines by taking the middle point as a reference, dividing the ground library plane image into a plurality of ground library subareas based on the first central line, and arranging at least one dehumidification device and detection device in each ground library subarea;

acquiring a sub-region center point of each regional warehouse sub-region and an access point of each regional warehouse entrance, calculating a dividing distance between each sub-region center point and each access point, determining an optimal warehouse entrance of each regional warehouse sub-region according to the dividing distance, and generating a sub-region set corresponding to each regional warehouse entrance according to each optimal warehouse entrance;

Acquiring current humidity corresponding to each regional warehouse subarea according to the detection equipment, if the regional warehouse subarea with the current humidity being greater than the preset humidity exists, determining the regional warehouse subarea as a first regional warehouse subarea, determining the regional warehouse subarea adjacent to the first regional warehouse subarea as a second regional warehouse subarea, controlling the dehumidification equipment in the first regional warehouse subarea to work according to a first power, and controlling the first number of dehumidification equipment in the second regional warehouse subarea to work according to a second power;

determining a subarea set where the first ground library subarea is located as a first subarea set, acquiring a rolling door unit corresponding to the first subarea set as a first rolling door unit, and controlling the working mode of the first rolling door unit to be switched from a normally open mode to an open-close mode.

In one possible implementation manner of the first aspect, optionally,

at least one dehumidifying device and at least one detecting device are arranged in each of the regional areas of the warehouse, and the dehumidifying device comprises:

obtaining the optimal areas of the dehumidification equipment efficacy of the dehumidification equipment and the optimal areas of the detection equipment efficacy of the detection equipment, obtaining the area of each regional warehouse sub-area, and comparing the optimal areas of the dehumidification equipment efficacy and the area of the detection equipment efficacy with the area of each regional warehouse sub-area respectively to obtain the quantity of the dehumidification equipment and the quantity of the detection equipment corresponding to each regional warehouse sub-area;

The number of the dehumidification devices and the number of the detection devices corresponding to each of the ground warehouse subareas are calculated through the following formulas,

wherein,,for the number of dehumidification plants in the ground reservoir subregion +.>Area of the ground pool subarea, +.>For the optimal area of the dehumidification device +.>For detecting the number of devices in a region of the ground pool, +.>The optimal area for detecting the efficacy of the equipment;

and arranging the dehumidifying equipment corresponding to the quantity of the dehumidifying equipment and the detecting equipment corresponding to the quantity of the detecting equipment in the corresponding ground warehouse subarea.

In one possible implementation manner of the first aspect, optionally,

the step of obtaining the sub-region center point of each of the ground library sub-regions comprises the following steps:

carrying out coordinate processing on the ground base plane image, and classifying coordinate points of each ground base subarea to obtain a subarea coordinate set corresponding to each ground base subarea;

obtaining a maximum horizontal value, a minimum horizontal value, a maximum vertical value and a minimum vertical value in each sub-region coordinate set;

obtaining a horizontal central coordinate value according to the intermediate value of the maximum horizontal value and the minimum horizontal value, obtaining a vertical central coordinate value according to the intermediate value of the maximum vertical value and the minimum vertical value, and combining the horizontal central coordinate value and the vertical central coordinate value to obtain a sub-region central point corresponding to each regional database.

In one possible implementation manner of the first aspect, optionally,

the step of obtaining the sub-region center point of each regional warehouse sub-region and the access point of each regional warehouse entrance, calculating the dividing distance between each sub-region center point and each access point, determining the optimal warehouse entrance of each regional warehouse sub-region according to the dividing distance, and generating a sub-region set corresponding to each regional warehouse entrance according to each optimal warehouse entrance, comprising:

determining access points of each ground garage entrance according to the ground garage plane image, obtaining access point coordinates of the access points of each ground garage entrance, and calculating the distance between the center point coordinates of the subareas and the access point coordinates of each ground garage entrance to obtain a plurality of dividing distances corresponding to each ground garage subarea and each ground garage entrance;

sorting a plurality of dividing distances corresponding to the regional sub-regions of the regional warehouse in a descending order to obtain a sorting list, screening out the shortest dividing distance from the last dividing distance in the sorting list, and determining the optimal regional entrance of each regional sub-region of the regional warehouse according to each shortest dividing distance;

and counting all the regional warehouse areas corresponding to the regional warehouse entrances and exits according to all the optimal regional warehouse entrances and exits, and generating a regional set corresponding to each regional warehouse entrance and exit.

In one possible implementation manner of the first aspect, optionally,

the step of collecting the current humidity corresponding to each of the ground warehouse subareas according to the detection device, determining the ground warehouse subareas as a first ground warehouse subarea and determining the ground warehouse subareas adjacent to the first ground warehouse subarea as a second ground warehouse subarea if the ground warehouse subareas with the current humidity being greater than the preset humidity exist, controlling the dehumidification devices in the first ground warehouse subareas to work according to the first power and controlling the first quantity of dehumidification devices in the second ground warehouse subareas to work according to the second power, and comprises the following steps:

acquiring the current humidity of each ground warehouse subarea in real time according to the detection equipment corresponding to the ground warehouse subarea, and if the current humidity corresponding to the ground warehouse subarea is greater than the preset humidity, marking the ground warehouse subarea to obtain a first ground warehouse subarea, and controlling the dehumidification equipment corresponding to the first ground warehouse subarea to work according to the first power;

marking the ground warehouse subareas adjacent to the first ground warehouse subareas to obtain a second ground warehouse subarea, determining a corresponding first number of dehumidification devices in the second ground warehouse subarea according to the area of the first ground warehouse subarea, and generating auxiliary working instructions according to the first number of dehumidification devices;

And according to the auxiliary working instruction, the dehumidification devices corresponding to the first quantity in the second ground warehouse area work according to the second power.

In one possible implementation manner of the first aspect, optionally,

the determining, according to the area of the first sub-area of the first ground warehouse, a corresponding first number of dehumidification devices in the second sub-area of the ground warehouse, and generating, according to the first number of dehumidification devices, an auxiliary work instruction includes:

the method comprises the steps of respectively obtaining the area of each first ground base subarea, and comparing the area of each first ground base subarea with the area of a preset ground base subarea to obtain equipment auxiliary proportion;

the number of the dehumidification devices of each second warehouse subarea is obtained, the number of the dehumidification devices of each second warehouse subarea and the auxiliary proportion of the devices are calculated, and the corresponding first number of the dehumidification devices in each second warehouse subarea is obtained;

generating an auxiliary working instruction according to the first number of the dehumidification devices in each second ground base subarea, and controlling the first number of the dehumidification devices in each second ground base subarea to work according to the second power based on the auxiliary working instruction.

In one possible implementation manner of the first aspect, optionally,

the obtaining a corresponding first number of dehumidification devices in each second warehouse sub-area includes:

counting the equipment coordinate points of each dehumidification equipment in each second regional warehouse to obtain a dehumidification equipment coordinate set corresponding to each second regional warehouse, and obtaining the distance between each equipment coordinate point in the dehumidification equipment coordinate set and the central point of the sub-region of the first regional warehouse to obtain a plurality of auxiliary equipment distances;

and carrying out ascending sort on the auxiliary equipment distances to obtain auxiliary equipment sorting tables corresponding to the second warehouse subareas, and sequentially selecting the dehumidification equipment corresponding to the first quantity in the auxiliary equipment sorting tables as the dehumidification equipment corresponding to the second warehouse subareas.

In one possible implementation manner of the first aspect, optionally,

the determining that the subarea set where the first local subarea is located is a first subarea set, obtaining a rolling door unit corresponding to the first subarea set as a first rolling door unit, and controlling the working mode of the first rolling door unit to be switched from a normally open mode to an open-close mode includes:

Acquiring the area number of a first ground warehouse subarea in a first subarea set, and determining a first time length influence coefficient of the first rolling shutter door unit according to the area number of the first ground warehouse subarea;

acquiring the area of a first ground warehouse subarea in a first subarea set, and determining a second duration influence coefficient of the first rolling shutter door unit according to the area of the first ground warehouse subarea;

and carrying out fusion adjustment on the standard working time length according to the first time length influence coefficient and the second time length influence coefficient to obtain the actual working time length of the first rolling shutter door unit in the opening and closing mode.

In one possible implementation manner of the first aspect, optionally,

before the region division is performed on the ground library plane image based on the first center line to obtain a plurality of ground library subareas, the method further comprises:

displaying the ground library plane image and the first central line, and calling a transparent adjustment chart layer to be overlapped above the ground library plane image in response to adjustment information of a user;

and receiving the movement information of the user on the first central line based on the transparent adjustment layer, and obtaining the moved first central line according to the movement information.

In a second aspect of the embodiment of the present invention, there is provided an underground garage condensation prevention control system, including:

the dividing unit is used for acquiring a ground library plane image, determining a plurality of ground library side lines according to the ground library plane image, determining the middle point of each ground library side line, generating a first central line perpendicular to the ground library side lines by taking the middle point as a reference, dividing the ground library plane image into a plurality of ground library subareas based on the first central line, and arranging at least one dehumidifying device and a detecting device in each ground library subarea;

the computing unit is used for obtaining the sub-region center point of each regional warehouse sub-region and the access points of each regional warehouse entrance and exit, computing the dividing distance between each sub-region center point and each access point, determining the optimal warehouse entrance and exit of each regional warehouse sub-region according to the dividing distance, and generating a sub-region set corresponding to each regional warehouse entrance and exit according to each optimal warehouse entrance and exit;

the control unit is used for acquiring the current humidity corresponding to each regional warehouse subarea according to the detection equipment, determining the regional warehouse subarea as a first regional warehouse subarea and determining the regional warehouse subarea adjacent to the first regional warehouse subarea as a second regional warehouse subarea if the current humidity is greater than the preset humidity, controlling the dehumidification equipment in the first regional warehouse subarea to work according to the first power, and controlling the first quantity of dehumidification equipment in the second regional warehouse subarea to work according to the second power;

The switching unit is used for determining a subarea set where the first ground warehouse subarea is located as a first subarea set, acquiring a rolling door unit corresponding to the first subarea set as a first rolling door unit, and controlling the working mode of the first rolling door unit to be switched from a normally open mode to an open-close mode.

In a third aspect of embodiments of the present invention, there is provided a storage medium having stored therein a computer program for implementing the method of the first aspect and the various possible designs of the first aspect when the computer program is executed by a processor.

According to the technical scheme provided by the invention, a plurality of ground garage side lines of the underground garage are determined according to the ground garage plane image. And (3) determining the middle point of each ground bank side line at the middle position of each ground bank side line, and drawing an auxiliary line perpendicular to each ground bank side line by taking the middle point of each ground bank side line as a reference to obtain a first central line perpendicular to each ground bank side line and corresponding to each ground bank side line. And dividing the ground garage plane image into areas according to the first central lines, so as to obtain a plurality of ground garage subareas of the underground garage. Calculating the center points and the access points of the subareas of the plurality of subareas of the underground garage to obtain the distances between the subareas of the different underground vaults and the different underground garage entrances and exits of the underground garage. The ground pool entrance that is shortest from the ground pool sub-area is marked as the optimal ground pool entrance corresponding to the ground pool sub-area. And carrying out statistics and generalization on the sub-regions of the ground warehouse corresponding to each ground warehouse entrance and exit to obtain a sub-region set corresponding to each ground warehouse entrance and exit. And collecting the current humidity corresponding to each ground warehouse subarea according to the dehumidifying equipment arranged in each ground warehouse subarea. If the current humidity of the local warehouse subarea is detected to be larger than the preset humidity, the local warehouse subarea is marked as a first local warehouse subarea. And controlling the dehumidifying equipment in the first warehouse area to work according to the first power. Meanwhile, a small amount of moisture can exist around the abnormal area, so that the scheme can also control the first number of dehumidification devices in the adjacent second warehouse subareas to assist the dehumidification operation of the abnormal area according to the second power. And marking the rolling door units corresponding to the first subarea set in the underground garage to obtain corresponding first rolling door units. The working mode of the first rolling door unit is controlled to be switched from a normally open mode to an open-close mode. The controller is gathered to the humiture of the different regions of underground garage wholly through humidity transducer, and the effectual dehumidifier to the different regions of underground garage carries out regulation control to realize with the linkage of rolling slats door, be favorable to underground garage to carry out efficient dehumidification work, simultaneously effectual saving electric energy reduces holistic running cost.

According to the technical scheme provided by the invention, a detection device is correspondingly arranged in each ground warehouse subarea, and the current humidity corresponding to each ground warehouse subarea is collected according to the dehumidification device arranged in each ground warehouse subarea. If the current humidity of the local warehouse subarea is detected to be larger than the preset humidity, the local warehouse subarea is marked as a first local warehouse subarea. The other local library sub-regions adjacent to the first local library sub-region are marked as second local library sub-regions. In order to efficiently and rapidly remove moisture in the first warehouse subarea so as to reduce dew formation, the scheme can control the dehumidifying equipment in the first warehouse subarea to work according to the maximum output power which can be achieved. Meanwhile, according to the scheme, the dehumidification equipment, of which one part is close to the first ground warehouse subarea, in the second ground warehouse subarea is screened to perform dehumidification according to the area size of the first ground warehouse subarea. And dehumidifying the adjacent areas of the ground warehouse subareas with abnormal humidity to assist in dehumidifying the abnormal areas. The efficient dehumidification work of the underground garage is facilitated, meanwhile, electric energy is effectively saved, and the overall operation cost is reduced.

According to the technical scheme provided by the invention, the sub-area set corresponding to the first ground garage sub-area in the underground garage is marked, so that the corresponding first sub-area set is obtained. A group of rolling door units are installed at the entrance and exit of the ground warehouse corresponding to each sub-area set, and when humidity abnormality occurs in the corresponding sub-area, the working mode of the corresponding rolling door is adjusted to be switched from a normally open mode to an open-close mode, so that invasion of moisture in the corresponding area is reduced. Meanwhile, when the number of the areas of the first ground garage subareas in the first subarea set is detected to be larger, the areas with the humidity larger than the preset humidity of the underground garage are described to be larger, and at the moment, the running time of the first rolling shutter door unit in the opening and closing mode can be adjusted, so that the running time of the opening and closing mode is longer, and the running time of the opening and closing mode is longer. And obtaining a first time length influence coefficient according to the area number of the first ground garage subareas in the underground garage. And obtaining a second duration influence coefficient according to the area of the first ground garage subarea in the underground garage. And carrying out fusion calculation on the two duration influence coefficients to obtain a total influence coefficient, and carrying out fusion adjustment on the standard working duration of the first rolling shutter door unit. And obtaining the actual working time of the first rolling door unit in the opening and closing mode. The working time length of the rolling door of the underground garage is effectively adjusted, so that effective dehumidification work of dehumidifiers in different areas of the underground garage is guaranteed. Meanwhile, efficient dehumidification of the whole underground garage is facilitated, electric energy is effectively saved, and the whole operation cost is reduced.

Drawings

FIG. 1 is a schematic flow chart of an anti-condensation control method of an underground garage;

fig. 2 is a schematic structural diagram of an anti-condensation control system of an underground garage.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms "first," "second," "third," "fourth" and the like in the description and in the claims and in the above drawings, if any, are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the invention described herein may be implemented in sequences other than those illustrated or otherwise described herein.

It should be understood that, in various embodiments of the present invention, the sequence number of each process does not mean that the execution sequence of each process should be determined by its functions and internal logic, and should not constitute any limitation on the implementation process of the embodiments of the present invention.

It should be understood that in the present invention, "comprising" and "having" and any variations thereof are intended to cover non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements that are expressly listed or inherent to such process, method, article, or apparatus.

It should be understood that in the present invention, "plurality" means two or more. "and/or" is merely an association relationship describing an association object, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. The character "/" generally indicates that the context-dependent object is an "or" relationship. "comprising A, B and C", "comprising A, B, C" means that all three of A, B, C comprise, "comprising A, B or C" means that one of the three comprises A, B, C, and "comprising A, B and/or C" means that any 1 or any 2 or 3 of the three comprises A, B, C.

It should be understood that in the present invention, "B corresponding to a", "a corresponding to B", or "B corresponding to a" means that B is associated with a, from which B can be determined. Determining B from a does not mean determining B from a alone, but may also determine B from a and/or other information. The matching of A and B is that the similarity of A and B is larger than or equal to a preset threshold value.

As used herein, "if" may be interpreted as "at … …" or "at … …" or "in response to a determination" or "in response to detection" depending on the context.

The technical scheme of the invention is described in detail below by specific examples. The following embodiments may be combined with each other, and some embodiments may not be repeated for the same or similar concepts or processes.

The invention provides an anti-condensation control method for an underground garage, which specifically comprises the following steps as shown in fig. 1:

s1, acquiring a ground library plane image, determining a plurality of ground library side lines according to the ground library plane image, determining the middle point of each ground library side line, generating a first central line perpendicular to the ground library side lines by taking the middle point as a reference, dividing the ground library plane image into a plurality of ground library subareas based on the first central line, and arranging at least one dehumidification device and a detection device in each ground library subarea.

The technical scheme provided by the invention is that the ground garage plane image is an image formed by the internal functional layout of the whole ground garage according to a horizontal projection method and a corresponding legend. Multiple ground garage edges of the underground garage can be determined according to the ground garage plane images. The ground garage side line is an edge line for forming the size of the ground garage. And determining the middle point of each ground bank side line at the middle position of each ground bank side line, and drawing an auxiliary line perpendicular to each ground bank side line by taking the middle point of each ground bank side line as a reference, so as to obtain each first central line perpendicular to each ground bank side line and corresponding to each ground bank side line.

And carrying out region division on the ground library plane image based on the first center line to obtain a plurality of ground library subareas. After each first central line corresponding to each side line of the library is prolonged, the first central lines intersect to form a plurality of areas. Therefore, the ground garage planar image is divided into a plurality of areas according to the plurality of first central lines, and a plurality of ground garage subareas of the underground garage can be obtained. The ground garage subareas are different areas of the underground garage divided according to the first central line corresponding to each ground garage side line.

It should be noted that, in general, the ground-pool plane image is often formed by ground-pool side lines in a straight line form, and the above-mentioned dividing manner is aimed at a scene that the ground-pool side lines are all straight lines, for example, the ground-pool plane image is polygonal, each side is a straight line, specifically, for example, a hexagon, so that six first central lines can be obtained in the present scheme. In other embodiments, the side line of the ground library may be a curve, in which case the corresponding first center line cannot be obtained in the present solution, and at this time, the present solution may perform region division in the following manner:

And (3) the ground library plane image is coordinated, and the maximum X-axis coordinate value, the minimum X-axis coordinate value, the maximum Y-axis coordinate value and the minimum Y-axis coordinate value of the ground library plane image are obtained. And connecting the maximum X-axis coordinate value and the minimum X-axis coordinate value to obtain a first region dividing line. And connecting the maximum Y-axis coordinate value and the minimum Y-axis coordinate value to obtain a second region dividing line. And carrying out region division on the irregular ground bank plane image with the ground bank side line being a curve according to the first region dividing line and the second region dividing line to obtain a plurality of ground bank subareas of the irregular ground bank plane image.

It should be noted that, in other embodiments, the user may also perform active region planning and division on the ground base plane image in advance according to his own requirement, and then input the divided ground base plane image into the server of the present scheme, where the server of the present scheme identifies regions in the divided ground base plane image, so as to obtain a plurality of ground base sub-regions.

In one possible implementation manner, in step S1 (at least one dehumidification device and at least one detection device are disposed in each of the warehouse sub-areas), the technical solution provided by the present invention specifically includes the following steps S11-S12, which are specifically as follows:

Step S11, obtaining the optimal areas of the dehumidification equipment efficacy of the dehumidification equipment and the optimal areas of the detection equipment efficacy of the detection equipment, obtaining the area of each regional warehouse sub-area, and comparing the optimal areas of the dehumidification equipment efficacy and the optimal areas of the detection equipment efficacy with the area of each regional warehouse sub-area respectively to obtain the quantity of the dehumidification equipment and the quantity of the detection equipment corresponding to each regional warehouse sub-area;

according to the technical scheme provided by the invention, the dehumidification equipment is a dehumidifier. The optimal effect area of the dehumidification equipment is the best applicable area of the dehumidification effect when the dehumidifier performs dehumidification work. The detection equipment is a humidity sensor and is mainly used for detecting the humidity of different ground garage subareas of the underground garage, so as to judge whether the subsequent dehumidification equipment controlling the different ground garage subareas works or not. The optimal area of the detection equipment is the best applicable area of the humidity detection effect when the humidity sensor performs the humidity detection work.

Comparing the optimal area of the dehumidification equipment with the area of each regional of the regional warehouse to obtain the quantity of the dehumidification equipment required to be installed in each regional warehouse. Comparing the optimal area of the efficacy of the detection equipment with the area of each regional database to obtain the number of the detection equipment corresponding to each regional database. For example, assume that the optimum area for dehumidification plant efficacy is 20 The area of one of the ground library subareas is 100 +.>And the number of the dehumidification devices which need to be installed in the sub-area of the ground warehouse can be obtained after comparison is 5. When the area of the local warehouse subarea is a non-integer, the number of the obtained dehumidification devices is generally an integer upwards. Assume that the optimal area for the efficacy of the detection device is 30 +.>The area of one of the ground library subareas is 120 +.>And then the number of detection devices which need to be installed in the ground warehouse subarea can be obtained after comparison is 4. When the area of the local library subarea is a non-integer, the number of the obtained detection devices is generally an integer upwards.

the technical proposal provided by the invention is that the area of the ground library subareaDivided by the optimal area of dehumidification plant efficacyTaking the integer upwards +.>Obtaining the number of dehumidification devices->. Area of ground pool subregion- >Number of dehumidification devicesProportional, area of local library subregion +.>The greater the corresponding number of dehumidification plants +.>The more; whereas the area of the local library subregion +.>The smaller the corresponding number of dehumidification devices +.>The fewer.

The technical proposal provided by the invention is that the area of the ground library subareaDivided by the optimum area for detecting equipment efficacyTaking the integer upwards +.>Obtaining the number of detection devices->. Area of ground pool subregion->And the number of detection devicesProportional, area of local library subregion +.>The larger the number of detection devices +.>The more; whereas the area of the local library subregion +.>The smaller the number of detection devices +.>The fewer.

Step S12, arranging the dehumidifying equipment corresponding to the quantity of the dehumidifying equipment and the detecting equipment corresponding to the quantity of the detecting equipment in the corresponding ground warehouse subarea.

According to the technical scheme provided by the invention, the obtained dehumidification devices with the number corresponding to the dehumidification devices in each regional warehouse and the detection devices with the number corresponding to the detection devices in each regional warehouse are installed and arranged in the corresponding regional warehouse.

In one possible implementation manner, before step S1 (the region division is performed on the ground library planar image based on the first center line to obtain a plurality of ground library sub-regions), the technical solution provided by the present invention further includes the following steps S13 to S14, which are specifically as follows:

Step S13, displaying the ground library plane image and the first central line, and calling a transparent adjustment chart layer to be overlapped above the ground library plane image in response to adjustment information of a user;

according to the technical scheme provided by the invention, the user's adjustment information is that when a worker finds that the difference of the size of the ground library subareas divided by the first central line is too large, the position of the first central line is adjusted, so that an information instruction for preparing adjustment is input. And displaying the ground library plane image and the position of the first central line on the control end, and calling the transparent layer to be overlapped above the ground library plane image according to the adjustment information input by the user. The transparent adjustment layer is a layer which is manually preset and can be covered on the ground library plane image. The method has the main effects that a user can adjust the first central line on the transparent adjustment layer to divide the ground library subareas.

And step S14, receiving movement information of the user on the first central line based on the transparent adjustment layer, and obtaining the moved first central line according to the movement information.

According to the technical scheme provided by the invention, the movement information can be the sliding trace of the first central line for sliding adjustment, and the current position of the first central line can be determined through the sliding trace. And receiving a sliding trace of the first central line sliding adjustment by the staff according to the transparent adjustment layer. And obtaining the moved first center line according to the sliding trace of the sliding adjustment of the first center line by the staff.

Step S2, obtaining a sub-region center point of each regional warehouse sub-region and an access point of each regional warehouse entrance, calculating a dividing distance between each sub-region center point and each access point, determining an optimal warehouse entrance of each regional warehouse sub-region according to the dividing distance, and generating a sub-region set corresponding to each regional warehouse entrance according to each optimal warehouse entrance.

According to the technical scheme provided by the invention, the center points of the subareas are the center point positions of different underground garage subareas of the underground garage. The entrance and exit of the ground garage are the entrance and exit of the underground garage vehicles, and the entrance and exit points are the positions of the entrance and exit of the ground garage. And calculating the acquired central point and the access point of the subarea to obtain the dividing distance. And dividing the distance to represent the distances between different underground garage subareas in the underground garage and different underground garage entrances and exits of the underground garage.

According to different dividing distances, determining distances from different ground warehouse subareas to different ground warehouse entrances and exits, selecting a ground warehouse entrance with the shortest distance to the ground warehouse subareas according to the dividing distances, and marking the ground warehouse entrance with the shortest distance to the ground warehouse subareas as an optimal ground warehouse entrance corresponding to the ground warehouse subareas. And carrying out statistics and summarization on the sub-regions of the ground warehouse corresponding to each ground warehouse entrance and exit according to the optimal ground warehouse entrance and exit to obtain a sub-region set corresponding to each ground warehouse entrance and exit.

For example, there are seven ground library sub-regions in total, corresponding to the numbers 1, 2, 3, 4, 5, 6, 7, respectively. There are three access points corresponding to the letters A, B, C. Acquiring a sub-region center point of a ground base sub-region 1, wherein the dividing distance from an access point of a ground base access point A to the access point A is ten meters; the center point of the subarea 1 to the access point of the subarea access point BThe dividing distance is fifteen meters; the division distance from the center point of the subarea of the ground warehouse subarea 1 to the access point of the ground warehouse entrance C is twenty-five meters. Then, according to ten meters, fifteen meters and twenty-five meters, the ground pool entrance with the shortest distance to the ground pool sub-area 1 is selected as the ground pool entrance A, so the ground pool entrance A is the optimal ground pool entrance of the ground pool sub-area 1. The optimal pool entrance and exit of the pool subarea 2 is obtained as a pool entrance and exit C according to the method; the optimal ground garage entrance and exit of the ground garage subarea 3 is a ground garage entrance and exit B; the optimal ground garage entrance and exit of the ground garage subarea 4 is a ground garage entrance and exit A; the optimal ground garage entrance and exit of the ground garage subarea 5 is a ground garage entrance and exit B; the optimal ground garage entrance and exit of the ground garage subarea 6 is a ground garage entrance and exit C; the optimal pool entrance and exit of the pool sub-area 7 is the pool entrance and exit a. The sub-areas of the ground warehouse corresponding to each ground warehouse entrance are counted and summarized according to the optimal ground warehouse entrance and exit, and then the sub-areas corresponding to the ground warehouse entrance and exit A are respectively obtained and collected as The method comprises the steps of carrying out a first treatment on the surface of the Sub-region set corresponding to ground garage entrance B +.>The method comprises the steps of carrying out a first treatment on the surface of the The sub-region set corresponding to the ground pool entrance C is +.>。

In one possible implementation manner, the step S2 (of obtaining the center point of each sub-region of the local library sub-region) specifically includes the following steps S21-S23, which are specifically as follows:

s21, carrying out coordinated processing on the ground base plane image, and classifying coordinate points of each ground base subarea to obtain a subarea coordinate set corresponding to each ground base subarea;

according to the technical scheme provided by the invention, the ground base plane image is subjected to coordinate processing to obtain a plurality of coordinate points corresponding to each ground base subarea one by one, and the coordinate points of each ground base subarea are unified and generalized to obtain a subarea coordinate set corresponding to each ground base subarea. The function of the subarea coordinate set is that the subarea center point of each subarea is convenient to calculate subsequently.

S22, obtaining a maximum horizontal value, a minimum horizontal value, a maximum vertical value and a minimum vertical value in each sub-region coordinate set;

the technical scheme provided by the invention is that the maximum horizontal value is the maximum X-axis coordinate value. The minimum level value is the minimum X-axis coordinate value. The maximum vertical value is the maximum Y-axis coordinate value. The minimum vertical value is the minimum Y-axis coordinate value. And obtaining the maximum X-axis coordinate value, the minimum X-axis coordinate value, the maximum Y-axis coordinate value and the minimum Y-axis coordinate value in the coordinate set of the sub-region corresponding to each regional database. And subsequent calculation of intermediate values of the X axis and the Y axis is facilitated.

And S23, obtaining a horizontal central coordinate value according to the intermediate value of the maximum horizontal value and the minimum horizontal value, obtaining a vertical central coordinate value according to the intermediate value of the maximum vertical value and the minimum vertical value, and combining the horizontal central coordinate value and the vertical central coordinate value to obtain a sub-region central point corresponding to each regional library.

According to the technical scheme provided by the invention, the horizontal center coordinate value is obtained by calculating according to the maximum X-axis coordinate value and the minimum X-axis coordinate value. The horizontal center coordinate value is one half of the sum of the maximum X-axis coordinate value and the minimum X-axis coordinate value, namely the middle coordinate value of the X-axis. And calculating according to the maximum Y-axis coordinate value and the minimum Y-axis coordinate value to obtain a vertical center coordinate value. The vertical central coordinate value is one half of the sum of the maximum Y-axis coordinate value and the minimum Y-axis coordinate value, namely the middle coordinate value of the Y axis. And finally, combining the horizontal central coordinate value and the vertical central coordinate value to obtain the sub-region central point of each regional database sub-region.

In one possible implementation manner, the step S2 (obtaining the sub-region center point of each regional sub-region and the access point of each regional access point, calculating the dividing distance between each sub-region center point and each access point, determining the optimal regional access point of each regional sub-region according to the dividing distance, and generating the sub-region set corresponding to each regional access point according to each optimal regional access point) specifically includes the following steps S24-S26, which specifically include:

Step S24, determining access points of all the ground warehouse entrances and exits according to the ground warehouse plane image, obtaining access point coordinates of the access points of all the ground warehouse entrances and exits, and calculating the distance between the center point coordinates of the subareas and the access point coordinates of all the ground warehouse entrances and exits to obtain a plurality of dividing distances corresponding to all the ground warehouse subareas and all the ground warehouse entrances and exits;

according to the technical scheme provided by the invention, the entrance and exit of the ground garage are the entrance and exit of the underground garage vehicle, and the entrance and exit point is the position of the entrance and exit of the ground garage. And determining the positions of the entrances and exits of each warehouse and the access points of the entrances and exits of each warehouse according to the warehouse plane image. And calculating the distance between the coordinates of the central point of the subarea of each regional warehouse and the coordinates of the access points of each regional warehouse entrance. And obtaining a plurality of dividing distances corresponding to the regional areas of each regional warehouse and the regional entrances and exits of each regional warehouse. And dividing the distance to represent the distances between different underground garage subareas in the underground garage and different underground garage entrances and exits of the underground garage. And determining the distances from different ground warehouse subareas to different ground warehouse entrances and exits according to different dividing distances.

Step S25, sorting a plurality of dividing distances corresponding to the regional sub-regions of the regional warehouse in a descending order to obtain a sorting list, screening out that the last dividing distance in the sorting list is the shortest dividing distance, and determining the optimal regional entrance and exit of each regional sub-region of the regional warehouse according to each shortest dividing distance;

According to the technical scheme provided by the invention, a plurality of dividing distances corresponding to each regional library are subjected to descending order and ordered to obtain an ordered list. The sorting list is preset by people and mainly aims at facilitating the subsequent selection of the shortest dividing distance. And screening out the shortest dividing distance from the last dividing distance in the ordered list according to the ordered list. And selecting a ground warehouse entrance with the shortest distance from the ground warehouse subareas according to the shortest dividing distance corresponding to each ground warehouse subarea. The ground pool entrance that is shortest from the ground pool sub-area is marked as the optimal ground pool entrance corresponding to the ground pool sub-area.

Step S26, counting each of the ground pool sub-areas corresponding to the ground pool entrance according to each of the optimal ground pool entrances and exits, and generating a sub-area set corresponding to each ground pool entrance and exit.

According to the technical scheme provided by the invention, the sub-region of the ground warehouse corresponding to each ground warehouse entrance is subjected to statistics and generalization according to the optimal ground warehouse entrance and exit, so as to obtain a sub-region set corresponding to each ground warehouse entrance and exit.

For example, there are seven ground library sub-regions in total, corresponding to the numbers 1, 2, 3, 4, 5, 6, 7, respectively. There are three access points corresponding to the letters A, B, C. Acquiring a sub-region center point of a ground base sub-region 1, wherein the dividing distance from an access point of a ground base access point A to the access point A is ten meters; the division distance from the center point of the subarea of the ground warehouse subarea 1 to the access point of the ground warehouse entrance B is fifteen meters; the division distance from the center point of the subarea of the ground warehouse subarea 1 to the access point of the ground warehouse entrance C is twenty-five meters. Then, according to ten meters, fifteen meters and twenty-five meters, the ground pool entrance with the shortest distance to the ground pool sub-area 1 is selected as the ground pool entrance A, so the ground pool entrance A is the optimal ground pool entrance of the ground pool sub-area 1. The optimal pool entrance and exit of the pool subarea 2 is obtained as a pool entrance and exit C according to the method; the optimal ground garage entrance and exit of the ground garage subarea 3 is a ground garage entrance and exit B; the optimal ground garage entrance and exit of the ground garage subarea 4 is a ground garage entrance and exit A; the optimal ground garage entrance and exit of the ground garage subarea 5 is a ground garage entrance and exit B; the optimal ground garage entrance and exit of the ground garage subarea 6 is a ground garage entrance and exit C; the optimal pool entrance and exit of the pool sub-area 7 is the pool entrance and exit a. The sub-areas of the ground warehouse corresponding to each ground warehouse entrance are counted and summarized according to the optimal ground warehouse entrance and exit, and then the sub-areas corresponding to the ground warehouse entrance and exit A are respectively obtained and collected as The method comprises the steps of carrying out a first treatment on the surface of the Sub-region set corresponding to ground garage entrance B +.>The method comprises the steps of carrying out a first treatment on the surface of the The sub-region set corresponding to the ground pool entrance C is +.>。

Step S3, collecting the current humidity corresponding to each regional warehouse sub-region according to the detection equipment, if the regional warehouse sub-region with the current humidity being larger than the preset humidity exists, determining the regional warehouse sub-region as a first regional warehouse sub-region, determining the regional warehouse sub-region adjacent to the first regional warehouse sub-region as a second regional warehouse sub-region, controlling the dehumidification equipment in the first regional warehouse sub-region to work according to the first power, and controlling the first quantity of dehumidification equipment in the second regional warehouse sub-region to work according to the second power.

According to the technical scheme provided by the invention, the detection equipment is a humidity sensor and is mainly used for detecting the humidity of different ground garage subareas of the underground garage, so that whether the subsequent dehumidification equipment of the different ground garage subareas is controlled to work is judged. And a detection device is correspondingly arranged in each ground warehouse subarea. The current humidity is the humidity value at the current moment. And collecting the current humidity corresponding to each ground warehouse subarea according to the dehumidifying equipment arranged in each ground warehouse subarea. The preset humidity is a standard humidity value corresponding to each warehouse subarea preset manually.

If the current humidity of the local warehouse subarea is detected to be larger than the preset humidity, the local warehouse subarea is marked as a first local warehouse subarea. The first ground warehouse subarea, namely, the humidity value of the ground warehouse subarea is abnormal, dew condensation is easy to form, and the dehumidification equipment of the ground warehouse subarea needs to be controlled to work subsequently. The other local library sub-regions adjacent to the first local library sub-region are marked as second local library sub-regions. The second ground bank sub-region is one or more other ground bank sub-regions adjacent and next to the first ground bank sub-region.

And controlling the dehumidifying equipment in the first warehouse area to work according to the first power. The dehumidifying equipment is a dehumidifier. The first power is the rated power of the dehumidifier. It is known that the current humidity in the first warehouse sub-area is greater than the preset humidity, and that it is necessary to efficiently and quickly remove the moisture in the first warehouse sub-area to avoid dew formation, so that the dehumidifying apparatus of the first warehouse sub-area is controlled to operate at the maximum output power that can be achieved.

And controlling the first number of dehumidification devices in the second reservoir sub-area to operate at the second power. The second power is half of the power of the dehumidifier when in operation. Since the second ground bank sub-area is adjacent to the first ground bank sub-area, there is a possibility that a small portion of the moisture of the first ground bank sub-area may spread into the adjacent second ground bank sub-area, thereby affecting the current humidity of the second ground bank sub-area. However, if the dehumidification device of the second warehouse sub-area also performs a dehumidification operation on that small portion of the moisture according to the rated power, unnecessary electric power is excessively consumed, and the cost of dehumidification is disadvantageously saved. Therefore, each second ground warehouse subarea adjacent to the first ground warehouse subarea needs to dehumidify the first number of dehumidification devices in the ground warehouse subarea according to half of the power of the dehumidifier when in operation.

The first number is a small part of the number of dehumidification devices in the second warehouse subarea, and the number of dehumidification devices is determined according to the area of the first warehouse subarea. It can be known that a certain number of dehumidification devices are arranged in the second warehouse subarea according to the area of the area, when the adjacent first warehouse subarea needs to perform dehumidification, all the dehumidification devices in the second warehouse subarea do not need to perform dehumidification, and only the dehumidification devices, of which a part is close to the first warehouse subarea, in the second warehouse subarea need to be screened according to the area of the first warehouse subarea. Therefore, the adjacent areas of the ground warehouse subareas with abnormal humidity can be dehumidified, and the moisture is prevented from spreading. The efficient dehumidification work of the underground garage is facilitated, meanwhile, electric energy is effectively saved, and the overall operation cost is reduced.

In a possible implementation manner, step S3 (according to the detection device, collecting the current humidity corresponding to each of the ground warehouse sub-areas, if there is a ground warehouse sub-area with the current humidity greater than the preset humidity, determining the ground warehouse sub-area as a first ground warehouse sub-area, determining the ground warehouse sub-area adjacent to the first ground warehouse sub-area as a second ground warehouse sub-area, controlling the dehumidifying devices in the first ground warehouse sub-area to work according to the first power, and controlling the first number of dehumidifying devices in the second ground warehouse sub-area to work according to the second power) specifically includes the following steps S31-S33, which specifically include:

Step S31, collecting the current humidity of each ground warehouse subarea in real time according to the detection equipment corresponding to the ground warehouse subarea, and if the current humidity corresponding to the ground warehouse subarea is greater than the preset humidity, marking the ground warehouse subarea to obtain a first ground warehouse subarea, and controlling the dehumidification equipment corresponding to the first ground warehouse subarea to work according to the first power;

according to the technical scheme provided by the invention, the current humidity corresponding to each ground warehouse subarea is collected according to the dehumidification equipment arranged in each ground warehouse subarea. The preset humidity is a standard humidity value corresponding to each warehouse subarea preset manually. If the current humidity of the local warehouse subarea is detected to be larger than the preset humidity, the local warehouse subarea is marked as a first local warehouse subarea. The first ground warehouse subarea, namely, the humidity value of the ground warehouse subarea is abnormal, dew is easy to form, and the dehumidification equipment of the ground warehouse subarea needs to be controlled to work subsequently.

The first power is the rated power of the dehumidifier. It is known that the current humidity in the first warehouse sub-area is greater than the preset humidity, and that it is necessary to efficiently and quickly remove the moisture in the first warehouse sub-area to avoid dew formation, so that the dehumidifying apparatus of the first warehouse sub-area is controlled to operate at the maximum output power that can be achieved.

Step S32, marking the ground warehouse subareas adjacent to the first ground warehouse subareas to obtain second ground warehouse subareas, determining a corresponding first number of dehumidification devices in the second ground warehouse subareas according to the area of the first ground warehouse subareas, and generating auxiliary working instructions according to the first number of dehumidification devices;

the technical scheme provided by the invention is that other local warehouse subareas adjacent to the first local warehouse subarea are marked as second local warehouse subareas. The second ground bank sub-region is one or more other ground bank sub-regions adjacent and next to the first ground bank sub-region. The first number is a small part of the number of dehumidification devices in the second warehouse subarea, and the number of dehumidification devices is determined according to the area of the first warehouse subarea.

It can be known that a certain number of dehumidification devices are arranged in the second warehouse subarea according to the area of the area, when the adjacent first warehouse subarea needs to perform dehumidification, all the dehumidification devices in the second warehouse subarea do not need to perform dehumidification, and only the dehumidification devices, of which a part is close to the first warehouse subarea, in the second warehouse subarea need to be screened according to the area of the first warehouse subarea. Therefore, the adjacent areas of the ground warehouse subareas with abnormal humidity can be dehumidified, and the moisture is prevented from spreading.

The auxiliary work order is thus generated in accordance with the first number of dehumidification apparatuses. The auxiliary work instruction is an instruction which is convenient for carrying out dehumidification work in cooperation with the first ground warehouse subarea and controlling the dehumidification equipment in the second ground warehouse subarea, and is convenient for carrying out auxiliary dehumidification work in the follow-up control of the dehumidification equipment in the second ground warehouse subarea.

And step S33, according to the auxiliary work instruction, the corresponding first number of dehumidification devices in the second warehouse area work according to the second power.

According to the technical scheme provided by the invention, after the control equipment receives the auxiliary work instruction, the first number of dehumidification equipment in the second ground warehouse subarea is controlled to work according to the second power. The second power is half of the power of the dehumidifier when in operation.

Since the second ground bank sub-area is adjacent to the first ground bank sub-area, there is a possibility that a small portion of the moisture of the first ground bank sub-area may spread into the adjacent second ground bank sub-area, thereby affecting the current humidity of the second ground bank sub-area. However, if the dehumidification device of the second warehouse sub-area also performs a dehumidification operation on that small portion of the moisture according to the rated power, unnecessary electric power is excessively consumed, and the cost of dehumidification is disadvantageously saved. Therefore, each second ground warehouse subarea adjacent to the first ground warehouse subarea needs to dehumidify the first number of dehumidification devices in the ground warehouse subarea according to half of the power of the dehumidifier when in operation.

In a possible implementation manner, the step S32 (determining a corresponding first number of dehumidification devices in the second local area according to the area of the first local area and generating an auxiliary work instruction according to the first number of dehumidification devices) specifically includes the following steps S321 to S323, which are specifically as follows:

step S321, respectively obtaining the area of each first ground warehouse sub-area, and comparing the area of each first ground warehouse sub-area with the area of a preset ground warehouse sub-area to obtain an equipment auxiliary proportion;

according to the technical scheme provided by the invention, the preset area of the ground warehouse subarea is the artificially preset area of the ground warehouse subarea. And acquiring the area of each first ground warehouse subarea, and comparing the area of each first ground warehouse subarea with the area of a preset ground warehouse subarea to obtain the auxiliary proportion of the equipment. The equipment auxiliary scale is the proportion of dehumidification equipment that needs each second warehouse sub-area.

Step S322, obtaining the number of dehumidification devices in each second warehouse subarea, and calculating the number of dehumidification devices in each second warehouse subarea and the auxiliary proportion of the devices to obtain a corresponding first number of dehumidification devices in each second warehouse subarea;

According to the technical scheme provided by the invention, the number of the dehumidification devices of each second ground warehouse subarea is obtained, and the number of the dehumidification devices of each second ground warehouse subarea and the auxiliary equipment proportion are calculated to obtain the dehumidification devices of the corresponding first number of each second ground warehouse subarea.

Step S323, generating an auxiliary working instruction according to the first number of dehumidification devices corresponding to the second sub-areas, and controlling the first number of dehumidification devices corresponding to the second sub-areas to work according to the second power based on the auxiliary working instruction.

According to the technical scheme provided by the invention, the auxiliary work instruction is generated according to the corresponding first number of dehumidification devices in each second warehouse subarea. And after receiving the auxiliary work instruction, the control equipment controls the first number of dehumidification equipment in the second ground warehouse area to work according to the second power.

In a possible implementation manner, the technical solution provided in the present invention, in step S322 (obtaining a corresponding first number of dehumidification devices in each second reservoir sub-area), specifically includes the following steps S3221-S3222, specifically as follows:

step S3221, counting the equipment coordinate points of each dehumidification equipment in each second regional warehouse to obtain a dehumidification equipment coordinate set corresponding to each second regional warehouse, and obtaining the distances between each equipment coordinate point in the dehumidification equipment coordinate set and the central point of the first regional warehouse to obtain a plurality of auxiliary equipment distances;

According to the technical scheme provided by the invention, the equipment coordinate points of each dehumidification equipment in each second warehouse subarea are counted to obtain the dehumidification equipment coordinate set corresponding to each second warehouse subarea. The equipment coordinate points are corresponding equipment coordinate points after each dehumidification equipment is coordinated based on each regional database. The dehumidifying equipment coordinate set is a set obtained by summarizing equipment coordinate points of each dehumidifying equipment in each second warehouse subarea. And acquiring and respectively calculating the coordinates of each equipment coordinate point corresponding to each dehumidification equipment in the dehumidification equipment coordinate set and the coordinates of the central point of the subarea of the first ground library to obtain a plurality of auxiliary equipment distances. The auxiliary equipment distance is the distance between each dehumidification equipment in each second warehouse subarea and the subarea center point of the first warehouse subarea.

Step S3222, performing ascending order on the auxiliary equipment distances to obtain auxiliary equipment ordering tables corresponding to the second warehouse subareas, and sequentially selecting the dehumidification equipment corresponding to the first number in the auxiliary equipment ordering tables as the dehumidification equipment corresponding to the second warehouse subareas.

According to the technical scheme provided by the invention, the auxiliary equipment distances corresponding to each dehumidification equipment in each second warehouse subarea are sequenced in an ascending order to obtain an auxiliary equipment sequencing table corresponding to each second warehouse subarea. The auxiliary equipment sorting table is a distance comparison table which is manually set according to the distance between each dehumidification equipment in each second warehouse subarea and the subarea center point of the first warehouse subarea, so that the dehumidification equipment in each second warehouse subarea which is close to the first warehouse subarea can be conveniently selected later.

And sequentially selecting the dehumidification devices corresponding to the first quantity in the auxiliary device sorting table as the dehumidification devices of the corresponding second ground warehouse subareas. And selecting the dehumidification equipment with the auxiliary equipment close to the first quantity of dehumidification equipment corresponding to each second warehouse subarea from the auxiliary equipment sorting table as the dehumidification equipment for assisting the first warehouse subarea in dehumidification work in the second warehouse subarea.

For example, 5 dehumidification devices need to be selected in each second sub-district of the ground, so as to assist the first sub-district of the ground in dehumidification. It is known that the first number is 5. In the auxiliary equipment sequencing table of one second ground warehouse subarea, the auxiliary equipment distances obtained according to ascending sequence are respectively 3 meters, 5 meters, 7 meters, 8 meters, 10 meters, 11 meters, 13 meters, 16 meters and 18 meters. In the auxiliary equipment sorting table, the dehumidification equipment with the first five auxiliary equipment close to each other needs to be selected, namely, dehumidification equipment with the auxiliary equipment distance of 3 meters, 5 meters, 7 meters, 8 meters and 10 meters corresponding to each other is selected, and the dehumidification equipment is assisted to perform dehumidification work on the first ground warehouse subarea.

Step S4, determining a subarea set where the first ground warehouse subarea is located as a first subarea set, acquiring a rolling door unit corresponding to the first subarea set as a first rolling door unit, and controlling the working mode of the first rolling door unit to be switched from a normally open mode to an open-close mode.

The technical scheme provided by the invention is that the first subarea set is obtained by marking the subarea set corresponding to the first subarea in the underground garage. The rolling door unit is a rolling door device arranged at the entrance and the exit of the underground garage, and is convenient for isolating air flow in the external environment so as to ensure the average humidity of the underground garage. It can be known that a group of rolling door units are installed at the entrance and exit of the ground warehouse corresponding to each sub-area set. And the first rolling door unit is used for marking the rolling door units corresponding to the first subarea set in the underground garage to obtain the corresponding first rolling door units.

And controlling the working mode of the first rolling door unit to be switched from a normally open mode to an open-close mode. Normally open mode is that the rolling slats door unit is under the normal circumstances of ground storehouse humidity generally, and the vehicle need not wait for the rolling slats door to open when going out, and the baffle on the rolling slats door is in folding normal all open state of packing up always. The shutter mode is that the shutter door unit is in the state that all the baffles on the shutter door are put down and closed all the time under the condition that the humidity of a ground warehouse is large and dew is easy to generate, the shutter door can be opened only when a vehicle enters and exits, the baffles on the shutter door can pass after the shutter door is closed to be folded and packed to be fully opened, and the baffles on the shutter door can be kept closed after the vehicle passes and then is put down. And when the existence of the first ground warehouse subarea is detected, the working mode of the first rolling shutter door unit corresponding to the first subarea set is controlled to be switched from a normally open mode to an open-close mode.

In one possible implementation manner, the step S4 (determining that the sub-area set where the first ground warehouse sub-area is located is a first sub-area set, obtaining a rolling shutter door unit corresponding to the first sub-area set as a first rolling shutter door unit, and controlling the working mode of the first rolling shutter door unit to be switched from a normally open mode to an open mode) specifically includes the following steps S41 to S43, which specifically include:

step S41, acquiring the area number of a first ground warehouse subarea in a first subarea set, and determining a first time length influence coefficient of the first rolling shutter door unit according to the area number of the first ground warehouse subarea;

according to the technical scheme provided by the invention, the first time length influence coefficient is a first adjustment value set for influencing the operation time length of the first rolling door unit, and is mainly determined according to the area number of the first ground garage subareas in the underground garage. When the number of the first ground garage subareas in the first subarea set is detected to be larger, the areas with the humidity larger than the preset humidity are indicated to be larger, and at the moment, the operation time length of the first rolling door unit is required to be adjusted, so that the humidity of the ground garage is ensured to be stable in a range where dew condensation cannot occur.

Step S42, obtaining the area of a first ground warehouse subarea in a first subarea set, and determining a second duration influence coefficient of the first rolling door unit according to the area of the first ground warehouse subarea;

according to the technical scheme provided by the invention, the second time length influence coefficient is a second adjustment value set for influencing the operation time length of the first roller shutter door unit, and is mainly determined according to the area of the first ground garage subarea in the underground garage. When the larger the area of the first ground garage subarea in the first subarea set is detected, the larger the area of the area, which indicates that the humidity of the underground garage is larger than the preset humidity, is, the running time of the first rolling door unit needs to be adjusted, so that the humidity of the underground garage is ensured to be stable in a range where dew does not occur.

And step S43, carrying out fusion adjustment on the standard working time according to the first time influence coefficient and the second time influence coefficient to obtain the actual working time of the first rolling door unit in the opening and closing mode.

The technical scheme provided by the invention has the advantages that the standard working time is manually preset and is the standard time when the first rolling door unit works normally. And carrying out fusion calculation on a first time length influence coefficient corresponding to the area number of the first ground warehouse subareas and a second time length influence coefficient corresponding to the area of the first ground warehouse subareas to obtain a total influence coefficient, and carrying out fusion adjustment on the standard working time length of the first rolling shutter door unit. And obtaining the actual working time of the first rolling door unit in the opening and closing mode.

In order to implement the anti-condensation control method of the underground garage provided by the invention, the invention also provides an anti-condensation control system of the underground garage, as shown in a structural schematic diagram of the system in fig. 2, comprising:

The present invention also provides a storage medium having stored therein a computer program for implementing the methods provided by the various embodiments described above when executed by a processor.

The storage medium may be a computer storage medium or a communication medium. Communication media includes any medium that facilitates transfer of a computer program from one place to another. Computer storage media can be any available media that can be accessed by a general purpose or special purpose computer. For example, a storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. The processor and the storage medium may reside in an application specific integrated circuit (Application Specific Integrated Circuits, ASIC for short). In addition, the ASIC may reside in a user device. The processor and the storage medium may reside as discrete components in a communication device. The storage medium may be read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tape, floppy disk, optical data storage device, etc.

The present invention also provides a program product comprising execution instructions stored in a storage medium. The at least one processor of the device may read the execution instructions from the storage medium, the execution instructions being executed by the at least one processor to cause the device to implement the methods provided by the various embodiments described above.

In the above embodiments of the terminal or the server, it should be understood that the processor may be a central processing unit (english: central Processing Unit, abbreviated as CPU), or may be other general purpose processors, digital signal processors (english: digital Signal Processor, abbreviated as DSP), application specific integrated circuits (english: application Specific Integrated Circuit, abbreviated as ASIC), or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of a method disclosed in connection with the present invention may be embodied directly in a hardware processor for execution, or in a combination of hardware and software modules in a processor for execution.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the 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 scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims

1. The anti-condensation control method for the underground garage is characterized by comprising the following steps of:

2. The method of claim 1, wherein the step of determining the position of the substrate comprises,

wherein (1)>For the number of dehumidification plants in the ground reservoir subregion +.>Area of the ground pool subarea, +.>For the optimal area of the dehumidification device +.>For detecting the number of devices in a region of the ground pool, +. >The optimal area for detecting the efficacy of the equipment;

3. The method of claim 2, wherein the step of determining the position of the substrate comprises,

4. The method of claim 3, wherein the step of,

5. The method of claim 4, wherein the step of determining the position of the first electrode is performed,

6. The method of claim 5, wherein the step of determining the position of the probe is performed,

7. The method of claim 6, wherein the step of providing the first layer comprises,

8. The method of claim 7, wherein the step of determining the position of the probe is performed,

9. The method of claim 1, wherein the step of determining the position of the substrate comprises,

10. An underground garage anti-condensation control system, comprising: