CN115344077A

CN115344077A - Supervision system and method for cement warehouse

Info

Publication number: CN115344077A
Application number: CN202210944484.XA
Authority: CN
Inventors: 江源; 韩冬阳; 胡友学; 胡雅涵; 万佳艺; 孙愚; 沈雪; 郭捷楠; 谭东杰; 张丹彤
Original assignee: Building Materials Industry Information Center
Current assignee: Building Materials Industry Information Center
Priority date: 2022-08-08
Filing date: 2022-08-08
Publication date: 2022-11-15
Anticipated expiration: 2042-08-08
Also published as: CN115344077B

Abstract

The invention relates to the technical field of cement storage, in particular to a monitoring system and a monitoring method for a cement warehouse. The method comprises the following steps: the in-bin acquisition module is used for acquiring in-bin parameter information in the cement warehouse in real time; the system comprises an outside-bin acquisition module, a monitoring module and a monitoring module, wherein the outside-bin acquisition module is used for acquiring outside-bin parameter information outside a cement warehouse in real time; the data acquisition module is used for acquiring parameter information in the warehouse and parameter information outside the warehouse; the image monitoring module is used for acquiring images of bagged cement stacked in an area in the cement warehouse in real time and judging the height change value of the bagged cement in the images within preset time; and the data processing module is used for adjusting the environmental humidity in the cement warehouse and the environmental temperature in the cement warehouse according to the height change value and the parameter information outside the warehouse. The invention can effectively realize real-time adjustment of the environment in the cement warehouse and ensure the quality of the stored cement.

Description

Supervision system and method for cement warehouse

Technical Field

The invention relates to the technical field of cement storage, in particular to a supervision system and a supervision method for a cement warehouse.

Background

Cement, powdered hydraulic inorganic cementing material. After being stirred by adding water, the mortar can be hardened in the air or in the water and can firmly bond sand, stone and other materials together. The mixture of early lime and pozzolan is very similar to modern lime-pozzolan cement, and concrete made by cementing broken stones with it not only has higher strength after hardening, but also can resist erosion of fresh water or salt-containing water. As an important cementing material, the high-performance cement is widely applied to engineering such as civil construction, water conservancy, national defense and the like for a long time.

Among the prior art, cement warehouse all need be built temporarily when building site uses cement, and when using cement warehouse to save cement, the humiture has great influence to the storage of cement, and current cement warehouse is at the in-process of storage, can't adjust in real time to the humiture environment in the warehouse, and then can exert an influence to the quality of the cement of storage. Therefore, how to provide a supervision system and a supervision method for a cement warehouse is a technical problem which needs to be solved urgently by a person skilled in the art.

Disclosure of Invention

The invention aims to provide a monitoring system and a monitoring method for a cement warehouse.

The invention improves the problem that the temperature and humidity environment in the cement warehouse can not be adjusted in real time in the storage process of the existing cement warehouse in the prior art, and further the quality of the stored cement can be influenced.

The invention improves the problem that the external environment of the cement warehouse in a climate variable area influences the interior of the warehouse in the prior art, and the invention corrects and optimizes the internal humidity of the warehouse in real time according to the external environment temperature and humidity of the cement warehouse by acquiring the external environment temperature and humidity of the cement warehouse in real time, thereby ensuring that the warehouse cannot receive the influence of the external temperature and humidity in any climate.

In order to achieve the purpose, the invention provides the following technical scheme:

a supervisory system for a cement warehouse, the interior of the cement warehouse being evenly divided into six zones, comprising:

the in-bin collection module is used for collecting in-bin parameter information in the cement bin in real time, wherein the in-bin parameter information comprises the ambient humidity W0 in the cement bin, the ambient temperature T0 in the cement bin and the quantity Q of bagged cement in the cement bin;

the system comprises an outside-warehouse acquisition module, a monitoring module and a control module, wherein the outside-warehouse acquisition module is used for acquiring outside-warehouse parameter information outside the cement warehouse in real time, and the outside-warehouse parameter information comprises the outside-cement-warehouse environment humidity U0 and the outside-cement-warehouse environment temperature P0;

the data acquisition module is used for acquiring the parameter information in the warehouse and the parameter information outside the warehouse;

the image monitoring module is used for respectively acquiring image data of the bagged cement stacked in the six areas in real time and determining the height value H0 of the bagged cement in the image data at the time t0, and the image monitoring module is also used for determining the height change value Delta S of the bagged cement within a preset time length after the time t0;

the data processing module is used for adjusting the environmental humidity W0 in the cement warehouse and the environmental temperature T0 in the cement warehouse according to the height change value Delta S and the parameter information outside the warehouse; wherein the content of the first and second substances,

when the Delta S is greater than 0, determining that the height value H0 of the bagged cement is increased, wherein the height value of the bagged cement is H0 plus Delta S, and H0 plus Delta S is less than or equal to 10;

and when the Delta S is less than 0, determining that the height value H0 of the bagged cement is reduced, wherein the height value of the bagged cement is H0-Delta S, and H0-Delta S is more than or equal to 0.

In some embodiments of the present application, the number of the image monitoring modules is at least 24, the image monitoring modules are disposed in four directions of six regions, and the image data of the bagged cement stacked in the six regions is collected in real time through the four directions.

In some embodiments of the present application, the data processing module is further configured to set an ambient humidity W01 in the first predetermined cement warehouse, an ambient humidity W02 in the second predetermined cement warehouse, an ambient humidity W03 in the third predetermined cement warehouse, and an ambient humidity W04 in the fourth predetermined cement warehouse, where W01 < W02 < W03 < W04 < 70% in 50%; the data processing module is further used for setting an absolute value S1 of a first preset height change value, an absolute value S2 of a second preset height change value, an absolute value S3 of a third preset height change value and an absolute value S4 of a fourth preset height change value, and S1 is greater than 0 and S2 is greater than S3 and S4 is less than or equal to 10;

the data processing module is further configured to, when the height value H0 of the bagged cement increases, select, according to a relationship between Δ S and an absolute value S1 of the first preset height variation value, an absolute value S2 of the second preset height variation value, an absolute value S3 of the third preset height variation value, and an absolute value S4 of the fourth preset height variation value, an environmental humidity in a corresponding preset cement warehouse as the environmental humidity in the cement warehouse;

when the delta S is less than S1, selecting the environmental humidity W01 in the first preset cement warehouse as the environmental humidity in the cement warehouse;

when S1 is larger than or equal to S2 and S is smaller than S2, selecting the environmental humidity W02 in the second preset cement warehouse as the environmental humidity in the cement warehouse;

when S2 is larger than or equal to S3 and delta S is smaller than S3, selecting the environmental humidity W03 in the third preset cement warehouse as the environmental humidity in the cement warehouse;

when S3 is larger than or equal to S4 and delta S is smaller than S4, selecting the environmental humidity W04 in the fourth preset cement warehouse as the environmental humidity in the cement warehouse;

the data processing module is further configured to, when the height value H0 of the bagged cement decreases, select, according to a relationship between Δ S and an absolute value S1 of the first preset height variation value, an absolute value S2 of the second preset height variation value, an absolute value S3 of the third preset height variation value, and an absolute value S4 of the fourth preset height variation value, an environmental humidity in a corresponding preset cement silo as the environmental humidity in the cement silo;

when the absolute delta S is less than S1, selecting the environmental humidity W04 in the fourth preset cement warehouse as the environmental humidity in the cement warehouse;

when S1 is less than or equal to | delta S | < S2, selecting the environmental humidity W03 in the third preset cement warehouse as the environmental humidity in the cement warehouse;

when S2 is less than or equal to | delta S | < S3, selecting the environmental humidity W02 in the second preset cement warehouse as the environmental humidity in the cement warehouse;

when S3 is less than or equal to | delta S | < S4, selecting the environmental humidity W01 in the first preset cement warehouse as the environmental humidity in the cement warehouse;

when the environment humidity W0i in the ith preset cement warehouse is selected as the environment humidity in the cement warehouse, i =1,2,3,4, the environment humidity in the cement warehouse is adjusted to be the environment humidity W0i in the ith preset cement warehouse.

In some embodiments of the application, the data obtaining module is further configured to calculate a difference X between an ambient humidity W0 inside the cement warehouse and an ambient humidity U0 outside the cement warehouse after obtaining the in-warehouse parameter information and the out-warehouse parameter information, where the difference X = W0-U0;

when X is less than 0, the environment humidity U0 outside the cement warehouse is greater than the environment humidity W0 inside the cement warehouse;

when X =0, the ambient humidity U0 outside the cement warehouse is equal to the ambient humidity W0 inside the cement warehouse;

when X is larger than 0, the environment humidity U0 outside the cement warehouse is smaller than the environment humidity W0 inside the cement warehouse;

the data processing module is further used for setting a preset humidity difference matrix M0 and an environment humidity correction coefficient matrix A in a preset cement warehouse, and setting A (A1, A2, A3, A4) for the environment humidity correction coefficient matrix A in the preset cement warehouse, wherein A1 is an environment humidity correction coefficient in a first preset cement warehouse, A2 is an environment humidity correction coefficient in a second preset cement warehouse, A3 is an environment humidity correction coefficient in a third preset cement warehouse, A4 is an environment humidity correction coefficient in a fourth preset cement warehouse, and A1 is greater than 0.6, A2 is greater than A3, A4 is less than 1.5; setting M0 (M01, M02, M03, M04) for the preset humidity difference matrix M0, wherein M01 is a first preset humidity difference, M02 is a second preset humidity difference, M03 is a third preset humidity difference, M04 is a fourth preset humidity difference, and M01 is more than M02 and less than M03 and less than M04;

the data processing module is further used for selecting a corresponding environment humidity correction coefficient according to the relation between the X and the preset humidity difference matrix M0 so as to correct the environment humidity in the cement warehouse;

when the height value H0 of the bagged cement is increased and the difference value X is smaller than 0, when X is smaller than M01, selecting an environmental humidity correction coefficient A1 in the first preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1W 01;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, and when M01 is less than or equal to X and less than M02, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 02;

when the height value H0 of the bagged cement is increased and the difference value X =0, the environmental humidity in the cement warehouse does not need to be corrected;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, when the M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A3 in the third preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3X W03;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, selecting an environmental humidity correction coefficient A4 in the fourth preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 04;

when the height value H0 of the bagged cement is reduced and the difference value X is smaller than 0, and when X is smaller than M01, selecting an environmental humidity correction coefficient A4 in the fourth preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 01;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, and when M01 is less than or equal to X and less than M02, selecting an environmental humidity correction coefficient A3 in the third preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3W 02;

when the height value H0 of the bagged cement is reduced and the difference value X =0, the environmental humidity in the cement warehouse does not need to be corrected;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, when the M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2X W03;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, when the height value H0 of the bagged cement is not less than M03 and less than M04, when the height value H0 of the bagged cement is increased and the difference value X is less than 0, selecting an environmental humidity correction coefficient A1 in the first preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1W 04;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, when X is smaller than M01, selecting an environmental humidity correction coefficient A4 in the fourth preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 01;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, and when M01 is not smaller than X and smaller than M02, selecting an environmental humidity correction coefficient A3 in the third preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3W 02;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, and when M02 is not larger than X and smaller than M03, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 03;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, when the height value H0 of the bagged cement is not larger than M03 and is smaller than M04, when the height value H0 of the bagged cement is increased and the difference value X is smaller than 0, selecting an environmental humidity correction coefficient A1 in the first preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1W 04;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when X is smaller than M01, selecting an environmental humidity correction coefficient A1 in the first preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1W 01;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when the M01 is larger than or equal to X and is smaller than M02, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 02;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, and when M02 is not larger than X and smaller than M03, selecting an environmental humidity correction coefficient A3 in the third preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3W 03;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when the height value H0 of the bagged cement is not larger than M03 and is smaller than M04, when the height value H0 of the bagged cement is increased and the difference value X is smaller than 0, selecting an environmental humidity correction coefficient A4 in the fourth preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 04.

In some embodiments of the present application, the data processing module is further configured to set a number matrix K0 of bagged cement stored in a preset cement warehouse and an ambient temperature matrix B in the preset cement warehouse, and set B (B1, B2, B3, B4) for the ambient temperature matrix B in the preset cement warehouse, where B1 is an ambient temperature in the first preset cement warehouse, B2 is an ambient temperature in the second preset cement warehouse, B3 is an ambient temperature in the third preset cement warehouse, B4 is an ambient temperature in the fourth preset cement warehouse, and B1 < B2 < B3 < B4 < 22 ℃ is greater than 18 ℃; setting K0 (K01, K02, K03, K04) for a matrix K0 of the number of bagged cement stored in the preset cement warehouse, wherein K01 is the number of the bagged cement in the first preset cement warehouse, K02 is the number of the bagged cement in the second preset cement warehouse, K03 is the number of the bagged cement in the third preset cement warehouse, K04 is the number of the bagged cement in the fourth preset cement warehouse, and K01 < K02 < K03 < K04;

the data processing module is further used for selecting corresponding ambient temperature as the ambient temperature in the cement warehouse according to the relation between Q and the matrix K0 of the number of bagged cement in the preset cement warehouse, and cooling the cement warehouse through an air conditioner;

when P0 is less than K01, selecting the environmental temperature B4 in the fourth preset cement warehouse as the environmental temperature in the cement warehouse;

when K01 is more than or equal to P0 and more than K02, selecting the environmental temperature B3 in the third preset cement warehouse as the environmental temperature in the cement warehouse;

when K02 is not less than P0 and not more than K03, selecting the environmental temperature B2 in the second preset cement warehouse as the environmental temperature in the cement warehouse;

and when K03 is not more than P0 and not more than K04, selecting the ambient temperature B1 in the first preset cement warehouse as the ambient temperature in the cement warehouse.

In some embodiments of the present application, the data processing module is further configured to calculate, in real time, a ratio Y between the amount E of bagged cement in each of six areas and the amount Q of bagged cement in the cement warehouse, where the ratio Y is E/Q;

the data processing module is further used for setting a bagged cement quantity ratio matrix G in a preset area and an environment temperature correction coefficient matrix e in a preset cement warehouse, and for the bagged cement quantity ratio matrix G in the preset area, setting G (G1, G2, G3, G4), wherein G1 is the bagged cement quantity ratio in the first preset area, G2 is the bagged cement quantity ratio in the second preset area, G3 is the bagged cement quantity ratio in the third preset area, G4 is the bagged cement quantity ratio in the fourth preset area, and G1 is more than or equal to 0, G2 is more than G3, G4 is more than or equal to 1/6; setting e (e 1, e2, e3, e 4) for the environment temperature correction coefficient matrix e in the preset cement warehouse, wherein e1 is the environment temperature correction coefficient in the first preset cement warehouse, e2 is the environment temperature correction coefficient in the second preset cement warehouse, e3 is the environment temperature correction coefficient in the third preset cement warehouse, e4 is the environment temperature correction coefficient in the fourth preset cement warehouse, and e1 is more than 0.8 and less than e2 and less than e3 and less than e4 and less than 1.2;

the data processing module is further used for selecting a corresponding correction coefficient according to the relation between the Y and the bagged cement quantity ratio matrix G in the preset area as the correction coefficient of the environmental temperature in the cement warehouse;

when Y is smaller than G1, selecting an environmental humidity correction coefficient e4 in the fourth preset cement warehouse to correct the environmental temperature B1 in the first preset cement warehouse, wherein the corrected environmental humidity is B1 × e4;

when the G1 is not more than Y and less than G2, selecting an environmental humidity correction coefficient e3 in the third preset cement warehouse to correct the environmental temperature B2 in the second preset cement warehouse, wherein the corrected environmental humidity is B2 × e3;

when the G2 is not less than Y and less than G3, selecting an environmental humidity correction coefficient e2 in the second preset cement warehouse to correct an environmental temperature B3 in the third preset cement warehouse, wherein the corrected environmental humidity is B3 × e2;

and when the G3 is not more than Y and less than G4, selecting an environmental humidity correction coefficient e1 in the first preset cement warehouse to correct the environmental temperature B4 in the fourth preset cement warehouse, wherein the corrected environmental humidity is B4 × e1.

In order to achieve the above object, the present invention also provides a method for supervising a cement warehouse, which divides the interior of the cement warehouse into six areas on average, including:

collecting parameter information in the cement warehouse in real time, wherein the parameter information in the warehouse comprises the environmental humidity W0 in the cement warehouse, the environmental temperature T0 in the cement warehouse and the quantity Q of bagged cement in the cement warehouse;

acquiring out-of-warehouse parameter information outside the cement warehouse in real time, wherein the out-of-warehouse parameter information comprises environment humidity U0 outside the cement warehouse and environment temperature P0 outside the cement warehouse;

acquiring the parameter information in the warehouse and the parameter information outside the warehouse;

respectively acquiring image data of the bagged cement stacked in the six areas in real time, and determining a height value H0 of the bagged cement in the image data at the time t0, wherein the image monitoring module is further used for determining a height change value Delta S of the bagged cement within a preset time length after the time t0;

adjusting the environmental humidity W0 in the cement warehouse and the environmental temperature T0 in the cement warehouse according to the height change value Delta S and the parameter information outside the warehouse; wherein the content of the first and second substances,

In some embodiments of the present application, the ambient humidity W01 in the first predetermined cement silo, the ambient humidity W02 in the second predetermined cement silo, the ambient humidity W03 in the third predetermined cement silo, and the ambient humidity W04 in the fourth predetermined cement silo are preset, and 50% < W01 < W02 < W03 < W04 < 70%; presetting an absolute value S1 of a first preset height change value, an absolute value S2 of a second preset height change value, an absolute value S3 of a third preset height change value and an absolute value S4 of a fourth preset height change value, wherein S1 is more than 0 and more than S2 and more than S3 and more than S4 is less than or equal to 10;

when the height value H0 of the bagged cement is increased, selecting the environment humidity in the corresponding preset cement warehouse as the environment humidity in the cement warehouse according to the relationship between the deltaS and the absolute value S1 of the first preset height change value, the absolute value S2 of the second preset height change value, the absolute value S3 of the third preset height change value and the absolute value S4 of the fourth preset height change value;

when the S1 is more than or equal to the Delta S and less than the S2, selecting the environmental humidity W02 in the second preset cement warehouse as the environmental humidity in the cement warehouse;

when the delta S is more than or equal to S3 and less than S4, selecting the environmental humidity W04 in the fourth preset cement warehouse as the environmental humidity in the cement warehouse;

when the height value H0 of the bagged cement is reduced, selecting the corresponding environmental humidity in the preset cement warehouse as the environmental humidity in the cement warehouse according to the relation between the Delta S and the absolute value S1 of the first preset height change value, the absolute value S2 of the second preset height change value, the absolute value S3 of the third preset height change value and the absolute value S4 of the fourth preset height change value;

when S2 is more than or equal to S < S3, selecting the environmental humidity W02 in the second preset cement warehouse as the environmental humidity in the cement warehouse;

when the environmental humidity W0i in the ith preset cement warehouse is selected as the environmental humidity in the cement warehouse, i =1,2,3,4, the environmental humidity in the cement warehouse is adjusted to be the environmental humidity W0i in the ith preset cement warehouse.

In some embodiments of the present application, after obtaining the parameter information inside the cement warehouse and the parameter information outside the cement warehouse, calculating a difference X between an ambient humidity W0 inside the cement warehouse and an ambient humidity U0 outside the cement warehouse, where the difference X = W0-U0;

presetting a preset humidity difference matrix M0 and an environment humidity correction coefficient matrix A in a preset cement warehouse, and setting A (A1, A2, A3, A4) for the environment humidity correction coefficient matrix A in the preset cement warehouse, wherein A1 is an environment humidity correction coefficient in a first preset cement warehouse, A2 is an environment humidity correction coefficient in a second preset cement warehouse, A3 is an environment humidity correction coefficient in a third preset cement warehouse, A4 is an environment humidity correction coefficient in a fourth preset cement warehouse, and A1 is more than 0.6 and more than A2 and more than A3 and more than A4 and less than 1.5; setting M0 (M01, M02, M03, M04) for the preset humidity difference matrix M0, wherein M01 is a first preset humidity difference, M02 is a second preset humidity difference, M03 is a third preset humidity difference, M04 is a fourth preset humidity difference, and M01 is more than M02 and less than M03 and less than M04;

selecting a corresponding environment humidity correction coefficient according to the relation between the X and the preset humidity difference matrix M0 to correct the environment humidity in the cement warehouse;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, when X is less than M01, selecting an environmental humidity correction coefficient A1 in the first preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1W 01;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, when the M01 is less than or equal to X and less than M02, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 02;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, and when M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A3 in the third preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3W 03;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, and when M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 03;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, and when M01 is not smaller than X and smaller than M02, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 02;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when the M02 is not smaller than X and is smaller than M03, selecting an environmental humidity correction coefficient A3 in the third preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3X W03;

In some embodiments of the present application, a number matrix K0 of bagged cement stored in a preset cement warehouse and an ambient temperature matrix B in the preset cement warehouse are preset, and B (B1, B2, B3, B4) is set for the ambient temperature matrix B in the preset cement warehouse, where B1 is an ambient temperature in a first preset cement warehouse, B2 is an ambient temperature in a second preset cement warehouse, B3 is an ambient temperature in a third preset cement warehouse, B4 is an ambient temperature in a fourth preset cement warehouse, and B1 < B2 < B3 < B4 < 22 ℃ is set at 18 ℃; setting K0 (K01, K02, K03, K04) for a matrix K0 of the number of bagged cements stored in the preset cement warehouse, wherein K01 is the number of the bagged cements in the first preset cement warehouse, K02 is the number of the bagged cements in the second preset cement warehouse, K03 is the number of the bagged cements in the third preset cement warehouse, K04 is the number of the bagged cements in the fourth preset cement warehouse, and K01 is more than K02 and is more than K03 and is more than K04;

selecting corresponding ambient temperature as the ambient temperature in the cement warehouse according to the relation between Q and the matrix K0 of the number of bagged cement in the preset cement warehouse, and cooling the cement warehouse through an air conditioner;

when K01 is more than or equal to P0 and less than K02, selecting the environmental temperature B3 in the third preset cement warehouse as the environmental temperature in the cement warehouse;

In some embodiments of the present application, calculating a ratio Y of the amount of bagged cement E in each of six said areas to the amount of bagged cement Q in said cement warehouse in real time, said ratio Y being E/Q;

presetting a bagged cement quantity ratio matrix G in a preset area and an environment temperature correction coefficient matrix e in a preset cement warehouse, and setting G (G1, G2, G3 and G4) for the bagged cement quantity ratio matrix G in the preset area, wherein G1 is the bagged cement quantity ratio in a first preset area, G2 is the bagged cement quantity ratio in a second preset area, G3 is the bagged cement quantity ratio in a third preset area, G4 is the bagged cement quantity ratio in a fourth preset area, and G1 is more than or equal to 0 and more than G2 and more than G3 and less than or equal to 1/6; setting e (e 1, e2, e3, e 4) for the environment temperature correction coefficient matrix e in the preset cement warehouse, wherein e1 is the environment temperature correction coefficient in the first preset cement warehouse, e2 is the environment temperature correction coefficient in the second preset cement warehouse, e3 is the environment temperature correction coefficient in the third preset cement warehouse, e4 is the environment temperature correction coefficient in the fourth preset cement warehouse, and e1 is more than 0.8, more than e2, more than e3, more than e4, and less than 1.2;

selecting a corresponding correction coefficient as a correction coefficient of the environmental temperature in the cement warehouse according to the relation between the Y and the bagged cement quantity ratio matrix G in the preset area;

when Y is less than G1, selecting an environmental humidity correction coefficient e4 in the fourth preset cement warehouse to correct the environmental temperature B1 in the first preset cement warehouse, wherein the corrected environmental humidity is B1 × e4;

when the G2 is not more than Y and less than G3, selecting an environmental humidity correction coefficient e2 in the second preset cement warehouse to correct the environmental temperature B3 in the third preset cement warehouse, wherein the corrected environmental humidity is B3 × e2;

The invention provides a monitoring system and a method for a cement warehouse, compared with the prior art, the monitoring system and the method have the beneficial effects that:

the method monitors the warehouse by monitoring the environmental humidity and the environmental temperature in the cement warehouse in real time and the quantity of the bagged cement stored in the cement warehouse, monitors the warehouse based on relevant parameter information of the cement warehouse, and can effectively ensure the quality of the bagged cement stored in the cement warehouse by adjusting the temperature and the humidity inside the cement warehouse in real time.

Drawings

FIG. 1 is a functional block diagram of a supervisory system for a cement warehouse in accordance with the present invention;

FIG. 2 is an isometric section of the cement silo of the present invention;

fig. 3 is a flow chart of a method of supervision of a cement warehouse according to the present invention.

Detailed Description

The following detailed description of embodiments of the present invention is provided in connection with the accompanying 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 application, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present application.

The terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless otherwise specified.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate member, or they may be connected to each other through an intermediate member. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

Among the prior art, cement warehouse all need be built temporarily when building site uses cement, and when using cement warehouse to save cement, the humiture has great influence to the storage of cement, and current cement warehouse is at the in-process of storage, can't adjust in real time to the humiture environment in the warehouse, and then can exert an influence to the quality of the cement of storage.

Therefore, the invention provides a monitoring system and a monitoring method for a cement warehouse, and the monitoring method and the monitoring system for the cement warehouse can effectively realize real-time regulation of the environment in the cement warehouse and ensure the quality of the stored cement.

Referring to fig. 1-2, the present invention provides a supervision system of a cement warehouse, the interior of which is divided into six areas on average, including:

the system comprises an in-bin acquisition module, a data processing module and a data processing module, wherein the in-bin acquisition module is used for acquiring in-bin parameter information in a cement bin in real time, and the in-bin parameter information comprises the environmental humidity W0 in the cement bin, the environmental temperature T0 in the cement bin and the quantity Q of bagged cement in the cement bin;

the system comprises an outside-bin acquisition module, a monitoring module and a control module, wherein the outside-bin acquisition module is used for acquiring outside-bin parameter information outside a cement warehouse in real time, and the outside-bin parameter information comprises outside-bin ambient humidity U0 and outside-bin ambient temperature P0 of the cement warehouse;

the data acquisition module is used for acquiring parameter information in the warehouse and parameter information outside the warehouse;

the image monitoring module is used for respectively acquiring image data of bagged cement stacked in six areas in real time and determining a height value H0 of the bagged cement in the image data at the time t0, and is also used for determining a height change value deltaS of the bagged cement within a preset time after the time t0;

the data processing module is used for adjusting the environmental humidity W0 in the cement warehouse and the environmental temperature T0 in the cement warehouse according to the height change value delta S and the parameter information outside the warehouse; wherein, the first and the second end of the pipe are connected with each other,

when the delta S is larger than 0, determining that the height value H0 of the bagged cement is increased, wherein the height value of the bagged cement is H0 plus delta S, and H0 plus delta S is less than or equal to 10;

It can be understood that the quality of the bagged cement stored in the cement warehouse can be effectively ensured by monitoring the environmental humidity and the environmental temperature in the cement warehouse and the quantity of the bagged cement stored in the cement warehouse in real time, supervising the warehouse based on the relevant parameter information of the cement warehouse and adjusting the temperature and the humidity in the cement warehouse in real time.

In a specific embodiment of the present application, the number of the image monitoring modules is at least 24, the image monitoring modules are disposed in four directions of the six areas, and image data of bagged cement stacked in the six areas is acquired in real time through the four directions.

In a specific embodiment of the present application, the data processing module is further configured to set an ambient humidity W01 in the first preset cement warehouse, an ambient humidity W02 in the second preset cement warehouse, an ambient humidity W03 in the third preset cement warehouse, and an ambient humidity W04 in the fourth preset cement warehouse, where W01 < W02 < W03 < W04 < 70% is greater than 50%; the data processing module is also used for setting an absolute value S1 of a first preset height change value, an absolute value S2 of a second preset height change value, an absolute value S3 of a third preset height change value and an absolute value S4 of a fourth preset height change value, and S1 is more than 0 and S2 is more than S3 and S4 is less than or equal to 10;

the data processing module is further used for selecting the corresponding environmental humidity in the preset cement warehouse as the environmental humidity in the cement warehouse according to the relation between the delta S and the absolute value S1 of the first preset height change value, the absolute value S2 of the second preset height change value, the absolute value S3 of the third preset height change value and the absolute value S4 of the fourth preset height change value when the height value H0 of the bagged cement is increased;

when S1 is larger than or equal to S1 and S2 is smaller than S2, selecting the environmental humidity W02 in the second preset cement warehouse as the environmental humidity in the cement warehouse;

when the S2 is more than or equal to the delta S and less than the S3, selecting the environmental humidity W03 in the third preset cement warehouse as the environmental humidity in the cement warehouse;

the data processing module is further used for selecting the environment humidity in the corresponding preset cement warehouse as the environment humidity in the cement warehouse according to the relation between the delta S and the absolute value S1 of the first preset height change value, the absolute value S2 of the second preset height change value, the absolute value S3 of the third preset height change value and the absolute value S4 of the fourth preset height change value when the height value H0 of the bagged cement is reduced;

when S2 is more than or equal to | delta S | < S3, selecting the environmental humidity W02 in the second preset cement warehouse as the environmental humidity in the cement warehouse;

and when the environmental humidity W0i in the ith preset cement warehouse is selected as the environmental humidity in the cement warehouse, i =1,2,3 and 4, adjusting the environmental humidity in the cement warehouse to be the environmental humidity W0i in the ith preset cement warehouse.

It can be understood that the invention properly adjusts the cement warehouse based on the height change value of the bagged cement in the cement warehouse, and when the height of the bagged cement is piled up to increase or decrease, the environment humidity in the cement warehouse is adjusted in real time to reach the optimal environment humidity of the current quantity of the bagged cement, thereby ensuring that the cement is not easy to be affected by moisture and improving the storage quality of the cement.

In a specific embodiment of the present application, the data obtaining module is further configured to calculate a difference X between an ambient humidity W0 inside the cement warehouse and an ambient humidity U0 outside the cement warehouse after obtaining the parameter information inside the warehouse and the parameter information outside the warehouse, where the difference X = W0-U0;

the data processing module is further used for setting a preset humidity difference matrix M0 and an environment humidity correction coefficient matrix A in a preset cement warehouse, and setting A (A1, A2, A3, A4) for the environment humidity correction coefficient matrix A in the preset cement warehouse, wherein A1 is an environment humidity correction coefficient in a first preset cement warehouse, A2 is an environment humidity correction coefficient in a second preset cement warehouse, A3 is an environment humidity correction coefficient in a third preset cement warehouse, A4 is an environment humidity correction coefficient in a fourth preset cement warehouse, and A1 is more than 0.6 and more than A1 and more than A2 and more than A3 and less than A4 and less than 1.5; setting M0 (M01, M02, M03, M04) for the preset humidity difference matrix M0, wherein M01 is a first preset humidity difference, M02 is a second preset humidity difference, M03 is a third preset humidity difference, M04 is a fourth preset humidity difference, and M01 is more than M02 and more than M03 and more than M04;

the data processing module is also used for selecting a corresponding environment humidity correction coefficient according to the relation between the X and the preset humidity difference matrix M0 so as to correct the environment humidity in the cement warehouse;

when the height value H0 of the bagged cement is increased and the difference value X is smaller than 0, when X is smaller than M01, selecting an environmental humidity correction coefficient A1 in a first preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1W 01;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, when the M01 is less than or equal to X and less than M02, selecting an environmental humidity correction coefficient A2 in a second preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2X W02;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, when M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A3 in a third preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3X W03;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, selecting an environmental humidity correction coefficient A4 in a fourth preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 04;

when the height value H0 of the bagged cement is reduced and the difference value X is smaller than 0, when X is smaller than M01, selecting an environmental humidity correction coefficient A4 in a fourth preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 01;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, and when M01 is less than or equal to X and less than M02, selecting an environmental humidity correction coefficient A3 in a third preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3X W02;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, when M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A2 in a second preset cement warehouse to correct the environmental humidity W03 in a third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2X W03;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, when the height value H0 of the bagged cement is not more than M03 and less than M04, when the height value H0 of the bagged cement is increased and the difference value X is less than 0, selecting an environmental humidity correction coefficient A1 in a first preset cement warehouse to correct the environmental humidity W04 in a fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1X W04;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, when X is smaller than M01, selecting an environmental humidity correction coefficient A4 in a fourth preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 01;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, and when the M01 is not more than X and is smaller than M02, selecting an environmental humidity correction coefficient A3 in a third preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3X W02;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, when the M02 is not larger than X and is smaller than M03, selecting an environmental humidity correction coefficient A2 in a second preset cement warehouse to correct the environmental humidity W03 in a third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2X W03;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, when the height value H0 of the bagged cement is not larger than M03 and is smaller than M04, when the height value H0 of the bagged cement is increased and the difference value X is smaller than 0, selecting an environmental humidity correction coefficient A1 in a first preset cement warehouse to correct the environmental humidity W04 in a fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1X W04;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when X is smaller than M01, selecting an environmental humidity correction coefficient A1 in a first preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1W 01;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, and when the M01 is not more than X and is smaller than M02, selecting an environmental humidity correction coefficient A2 in a second preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 02;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when the M02 is not larger than X and is smaller than M03, selecting an environmental humidity correction coefficient A3 in a third preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3X W03;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when the height value H0 of the bagged cement is not larger than M03 and is smaller than M04, when the height value H0 of the bagged cement is increased and the difference value X is smaller than 0, selecting an environmental humidity correction coefficient A4 in a fourth preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 04.

It can be understood that due to different regional climates, humidity difference can be generated in the inner bin and the outer bin after the cement warehouse is built, so that when the fan dehumidification is carried out, the air outside the bin can be introduced to a certain degree, and further the air outside the bin can damage the humidity balance in the bin.

In a specific embodiment of the application, the data processing module is further configured to set a matrix K0 of the number of bagged cements stored in the preset cement warehouse and a matrix B of ambient temperatures in the preset cement warehouse, and set B (B1, B2, B3, B4) for the matrix B of ambient temperatures in the preset cement warehouse, where B1 is an ambient temperature in the first preset cement warehouse, B2 is an ambient temperature in the second preset cement warehouse, B3 is an ambient temperature in the third preset cement warehouse, B4 is an ambient temperature in the fourth preset cement warehouse, and B1 < B2 < B3 < B4 < 22 ℃ is greater than 18 ℃; setting K0 (K01, K02, K03, K04) for a matrix K0 of the number of bagged cement stored in the preset cement warehouse, wherein K01 is the number of the bagged cement in the first preset cement warehouse, K02 is the number of the bagged cement in the second preset cement warehouse, K03 is the number of the bagged cement in the third preset cement warehouse, K04 is the number of the bagged cement in the fourth preset cement warehouse, and K01 < K02 < K03 < K04;

the data processing module is also used for selecting corresponding ambient temperature as the ambient temperature in the cement warehouse according to the relation between Q and a matrix K0 of the number of bagged cement in the preset cement warehouse, and cooling the cement warehouse through an air conditioner;

when P0 is less than K01, selecting the environmental temperature B4 in a fourth preset cement warehouse as the environmental temperature in the cement warehouse;

when K01 is more than or equal to P0 and less than K02, selecting the environmental temperature B3 in a third preset cement warehouse as the environmental temperature in the cement warehouse;

when K02 is not less than P0 and less than K03, selecting the environmental temperature B2 in the second preset cement warehouse as the environmental temperature in the cement warehouse;

and when K03 is more than or equal to P0 and less than K04, selecting the ambient temperature B1 in the first preset cement warehouse as the ambient temperature in the cement warehouse.

It can be understood that the environmental temperature also influences the storage of the cement, and the cement is easy to be coagulated and hardened in the environment with high temperature, so that the environmental temperature is adjusted in real time based on the quantity of the bagged cement in the cement warehouse, and the storage quality of the cement is effectively improved.

In a specific embodiment of the application, the data processing module is further configured to calculate a ratio Y between the number E of bagged cement in each of the six areas and the number Q of bagged cement in the cement warehouse in real time, where the ratio Y is E/Q;

the data processing module is further used for setting a bagged cement quantity ratio matrix G in the preset area and an environment temperature correction coefficient matrix e in the preset cement warehouse, and for the bagged cement quantity ratio matrix G in the preset area, G (G1, G2, G3, G4) is set, wherein G1 is the bagged cement quantity ratio in the first preset area, G2 is the bagged cement quantity ratio in the second preset area, G3 is the bagged cement quantity ratio in the third preset area, G4 is the bagged cement quantity ratio in the fourth preset area, and G1 is more than or equal to 0, G2 is more than or equal to G3, G4 is more than or equal to 1/6; setting e (e 1, e2, e3, e 4) for an environment temperature correction coefficient matrix e in a preset cement warehouse, wherein e1 is an environment temperature correction coefficient in a first preset cement warehouse, e2 is an environment temperature correction coefficient in a second preset cement warehouse, e3 is an environment temperature correction coefficient in a third preset cement warehouse, e4 is an environment temperature correction coefficient in a fourth preset cement warehouse, and e1 is more than 0.8 and less than e2 and less than e3 and less than e4 and less than 1.2;

the data processing module is also used for selecting a corresponding correction coefficient according to the relation between the Y and a preset area bagged cement quantity ratio matrix G as a correction coefficient of the environmental temperature in the cement warehouse;

when Y is smaller than G1, selecting an environmental humidity correction coefficient e4 in a fourth preset cement warehouse to correct the environmental temperature B1 in the first preset cement warehouse, wherein the corrected environmental humidity is B1 × e4;

when G1 is not more than Y and less than G2, selecting an environmental humidity correction coefficient e3 in a third preset cement warehouse to correct the environmental temperature B2 in the second preset cement warehouse, wherein the corrected environmental humidity is B2 × e3;

when G2 is not more than Y and less than G3, selecting an environmental humidity correction coefficient e2 in the second preset cement warehouse to correct the environmental temperature B3 in the third preset cement warehouse, wherein the corrected environmental humidity is B3 × e2;

and when the G3 is less than or equal to Y and less than G4, selecting an environmental humidity correction coefficient e1 in the first preset cement warehouse to correct the environmental temperature B4 in the fourth preset cement warehouse, wherein the corrected environmental humidity is B4 × e1.

It can be understood that when bagged cement is stacked, the phenomenon that workers can not uniformly stack the bagged cement in six areas can be caused, more partial areas are stacked, and cement is not accumulated in the partial areas, so that the cement can influence the temperature and the humidity of the nearby environment in the region where the bagged cement is accumulated in a gathering manner, and the temperature and the humidity of the whole cement warehouse are influenced because the environment is not influenced in the region where the cement is accumulated, so that the temperature and the humidity environment in the whole cement warehouse can be changed regionally to influence the temperature and the humidity of the whole interior.

Based on the same technical concept, referring to fig. 3, the present invention also provides a method for supervising a cement warehouse, which divides the interior of the cement warehouse into six areas on average, including:

collecting parameter information in a cement warehouse in real time, wherein the parameter information in the warehouse comprises the environmental humidity W0 in the cement warehouse, the environmental temperature T0 in the cement warehouse and the quantity Q of bagged cement in the cement warehouse;

acquiring parameter information in a bin and parameter information outside the bin;

the method comprises the steps that image data of bagged cement stacked in six areas are collected in real time respectively, the height value H0 of the bagged cement in the image data at the time t0 is determined, and an image monitoring module is further used for determining the height change value delta S of the bagged cement within a preset time length after the time t0;

when the Delta S is greater than 0, determining that the height value H0 of the bagged cement is increased, wherein the height value of the bagged cement is H0+ Delta S, and H0+ Delta S is less than or equal to 10;

The method can monitor the warehouse by monitoring the environmental humidity and the environmental temperature in the cement warehouse and the quantity of the bagged cement stored in the cement warehouse in real time, monitors the warehouse based on the relevant parameter information of the cement warehouse, and can effectively ensure the quality of the bagged cement stored in the cement warehouse by adjusting the temperature and the humidity in the cement warehouse in real time.

In a specific embodiment of the present application, the ambient humidity W01 in the first preset cement warehouse, the ambient humidity W02 in the second preset cement warehouse, the ambient humidity W03 in the third preset cement warehouse, and the ambient humidity W04 in the fourth preset cement warehouse are preset, and W01 < W02 < W03 < W04 < 70% in 50%; presetting an absolute value S1 of a first preset height change value, an absolute value S2 of a second preset height change value, an absolute value S3 of a third preset height change value and an absolute value S4 of a fourth preset height change value, wherein S1 is more than 0 and more than S2 and more than S3 and more than S4 is less than or equal to 10;

when the height value H0 of the bagged cement is increased, selecting the environment humidity in the corresponding preset cement warehouse as the environment humidity in the cement warehouse according to the relationship between the delta S and the absolute value S1 of the first preset height change value, the absolute value S2 of the second preset height change value, the absolute value S3 of the third preset height change value and the absolute value S4 of the fourth preset height change value;

when the delta S is smaller than S1, selecting the environmental humidity W01 in the first preset cement warehouse as the environmental humidity in the cement warehouse;

when the height value H0 of the bagged cement is reduced, selecting the environment humidity in the corresponding preset cement warehouse as the environment humidity in the cement warehouse according to the relation between the delta S and the absolute value S1 of the first preset height change value, the absolute value S2 of the second preset height change value, the absolute value S3 of the third preset height change value and the absolute value S4 of the fourth preset height change value;

when S1 is more than or equal to | delta S | < S2, selecting the environmental humidity W03 in the third preset cement warehouse as the environmental humidity in the cement warehouse;

when S3 is more than or equal to S < S4, selecting the environmental humidity W01 in the first preset cement warehouse as the environmental humidity in the cement warehouse;

In a specific embodiment of the application, after acquiring parameter information inside a cement warehouse and parameter information outside the cement warehouse, calculating a difference X between an ambient humidity W0 inside the cement warehouse and an ambient humidity U0 outside the cement warehouse, wherein the difference X = W0-U0;

presetting a preset humidity difference matrix M0 and an environment humidity correction coefficient matrix A in a preset cement warehouse, and setting A (A1, A2, A3, A4) for the environment humidity correction coefficient matrix A in the preset cement warehouse, wherein A1 is an environment humidity correction coefficient in a first preset cement warehouse, A2 is an environment humidity correction coefficient in a second preset cement warehouse, A3 is an environment humidity correction coefficient in a third preset cement warehouse, A4 is an environment humidity correction coefficient in a fourth preset cement warehouse, and A1 is more than 0.6 and more than A2 and more than A3 and more than A4 and less than 1.5; setting M0 (M01, M02, M03, M04) for the preset humidity difference matrix M0, wherein M01 is a first preset humidity difference, M02 is a second preset humidity difference, M03 is a third preset humidity difference, M04 is a fourth preset humidity difference, and M01 is greater than M02 and less than M03 and less than M04;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, and when M01 is less than or equal to X and less than M02, selecting an environmental humidity correction coefficient A2 in a second preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 02;

when the height value H0 of the bagged cement is increased and the difference value X is less than 0, and when M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A3 in a third preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3X W03;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, and when M02 is less than or equal to X and less than M03, selecting an environmental humidity correction coefficient A2 in a second preset cement warehouse to correct the environmental humidity W03 in a third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 03;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, and when M02 is not larger than X and smaller than M03, selecting an environmental humidity correction coefficient A2 in a second preset cement warehouse to correct the environmental humidity W03 in a third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2W 03;

when the height value H0 of the bagged cement is reduced and the difference value X is larger than 0, when the height value H0 of the bagged cement is larger than or equal to M03 and smaller than M04, when the height value H0 of the bagged cement is increased and the difference value X is smaller than 0, selecting an environmental humidity correction coefficient A4 in a fourth preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4X W04.

In a specific embodiment of the present application, a quantity matrix K0 of bagged cement stored in a preset cement warehouse and an environment temperature matrix B in the preset cement warehouse are preset, and for the environment temperature matrix B in the preset cement warehouse, B (B1, B2, B3, B4) is set, where B1 is an environment temperature in the first preset cement warehouse, B2 is an environment temperature in the second preset cement warehouse, B3 is an environment temperature in the third preset cement warehouse, B4 is an environment temperature in the fourth preset cement warehouse, and B1 < B2 < B3 < B4 < 22 ℃ is set in advance; setting K0 (K01, K02, K03, K04) for a matrix K0 of the number of bagged cement stored in the preset cement warehouse, wherein K01 is the number of the bagged cement in the first preset cement warehouse, K02 is the number of the bagged cement in the second preset cement warehouse, K03 is the number of the bagged cement in the third preset cement warehouse, K04 is the number of the bagged cement in the fourth preset cement warehouse, and K01 < K02 < K03 < K04;

selecting corresponding ambient temperature as the ambient temperature in the cement warehouse according to the relation between Q and a matrix K0 for presetting the quantity of bagged cement in the cement warehouse, and cooling the cement warehouse through an air conditioner;

when K02 is more than or equal to P0 and less than K03, selecting the environmental temperature B2 in the second preset cement warehouse as the environmental temperature in the cement warehouse;

and when K03 is not more than P0 and not more than K04, selecting the environmental temperature B1 in the first preset cement warehouse as the environmental temperature in the cement warehouse.

It can be understood that the storage of the cement is also influenced by the ambient temperature, and the cement is very easy to be coagulated and hardened in the environment with high temperature, so that the storage quality of the cement is effectively improved by adjusting the ambient temperature in real time based on the quantity of bagged cement in the cement warehouse.

In a specific embodiment of the application, calculating the ratio Y of the quantity E of the bagged cement in each area of the six areas to the quantity Q of the bagged cement in the cement warehouse in real time, wherein the ratio Y is E/Q;

presetting a bagged cement quantity ratio matrix G in a preset area and an environment temperature correction coefficient matrix e in a preset cement warehouse, and setting G (G1, G2, G3 and G4) for the bagged cement quantity ratio matrix G in the preset area, wherein G1 is the bagged cement quantity ratio in a first preset area, G2 is the bagged cement quantity ratio in a second preset area, G3 is the bagged cement quantity ratio in a third preset area, G4 is the bagged cement quantity ratio in a fourth preset area, and G1 is more than or equal to 0, G2 is more than G3, G4 is more than or equal to 1/6; setting e (e 1, e2, e3, e 4) for an environment temperature correction coefficient matrix e in a preset cement warehouse, wherein e1 is an environment temperature correction coefficient in a first preset cement warehouse, e2 is an environment temperature correction coefficient in a second preset cement warehouse, e3 is an environment temperature correction coefficient in a third preset cement warehouse, e4 is an environment temperature correction coefficient in a fourth preset cement warehouse, and e1 is more than 0.8, more than e2, more than e3, more than e4 and less than 1.2;

selecting a corresponding correction coefficient as a correction coefficient of the environmental temperature in the cement warehouse according to the relation between the Y and a preset area bagged cement quantity ratio matrix G;

when Y is less than G1, selecting an environmental humidity correction coefficient e4 in a fourth preset cement warehouse to correct the environmental temperature B1 in the first preset cement warehouse, wherein the corrected environmental humidity is B1 × e4;

In summary, the invention monitors the environmental humidity and the environmental temperature in the cement warehouse and the quantity of the bagged cement stored in the cement warehouse in real time, supervises the warehouse based on the related parameter information of the cement warehouse, and can effectively ensure the quality of the bagged cement stored in the cement warehouse by adjusting the temperature and the humidity in the cement warehouse in real time.

The above is only an embodiment of the present invention, but the scope of the present invention should not be limited thereby, and any structural changes made according to the present invention should be considered as being limited within the scope of the present invention without departing from the gist of the present invention. It can be clearly understood by those skilled in the art that, for convenience and simplicity of description, the specific working process and related description of the system described above may refer to the corresponding process in the foregoing method embodiment, and details are not described herein again.

It should be noted that, the system provided in the foregoing embodiment is only illustrated by dividing the functional modules, and in practical applications, the functions may be distributed by different functional modules according to needs, that is, the modules or steps in the embodiments of the present invention are further decomposed or combined, for example, the modules in the foregoing embodiment may be combined into one module, or may be further split into multiple sub-modules, so as to complete all or part of the functions described above. The names of the modules and steps involved in the embodiments of the present invention are only for distinguishing the modules or steps, and are not to be construed as unduly limiting the present invention.

Those of skill in the art would appreciate that the various illustrative modules, method steps, and programs described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the software modules, method steps, and corresponding programs may be located in Random Access Memory (RAM), memory, read Only Memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art. To clearly illustrate this interchangeability of electronic hardware and software, various illustrative components and steps have been described above generally in terms of their functionality. Whether such functionality is implemented as electronic hardware or software depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Claims

1. A supervisory system for a cement warehouse, the interior of which is divided on average into six zones, comprising:

the data processing module is used for adjusting the environmental humidity W0 in the cement warehouse and the environmental temperature T0 in the cement warehouse according to the height change value deltaS and the parameter information outside the warehouse; wherein, the first and the second end of the pipe are connected with each other,

2. The supervision system for cement warehouses according to claim 1,

the data processing module is also used for setting the environmental humidity W01 in the first preset cement warehouse, the environmental humidity W02 in the second preset cement warehouse, the environmental humidity W03 in the third preset cement warehouse and the environmental humidity W04 in the fourth preset cement warehouse, wherein W01 is more than 50 percent and W02 is more than W03 is more than W04 and less than 70 percent; the data processing module is also used for setting an absolute value S1 of a first preset height change value, an absolute value S2 of a second preset height change value, an absolute value S3 of a third preset height change value and an absolute value S4 of a fourth preset height change value, and S1 is greater than 0 and S2 is greater than S3 and S4 is less than or equal to 10;

the data processing module is further configured to select, as the ambient humidity in the cement warehouse, the ambient humidity in the corresponding preset cement warehouse according to a relationship between Δ S and an absolute value S1 of the first preset height variation value, an absolute value S2 of the second preset height variation value, an absolute value S3 of the third preset height variation value, and an absolute value S4 of the fourth preset height variation value when the height value H0 of the bagged cement increases;

3. The supervision system for cement warehouses according to claim 2,

the data acquisition module is further configured to calculate a difference X between an ambient humidity W0 inside the cement warehouse and an ambient humidity U0 outside the cement warehouse after acquiring the parameter information inside the warehouse and the parameter information outside the warehouse, where the difference X = W0-U0;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, when X is less than M01, selecting an environmental humidity correction coefficient A4 in the fourth preset cement warehouse to correct the environmental humidity W01 in the first preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A4W 01;

when the height value H0 of the bagged cement is reduced and the difference value X is less than 0, when the height value H0 of the bagged cement is not less than M03 and less than M04, when the height value H0 of the bagged cement is increased and the difference value X is less than 0, selecting an environmental humidity correction coefficient A1 in the first preset cement warehouse to correct the environmental humidity W04 in the fourth preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A1X W04;

4. The supervision system for cement warehouses according to claim 1,

the data processing module is further used for setting a quantity matrix K0 of bagged cement stored in a preset cement warehouse and an environment temperature matrix B in the preset cement warehouse, and setting B (B1, B2, B3, B4) for the environment temperature matrix B in the preset cement warehouse, wherein B1 is the environment temperature in the first preset cement warehouse, B2 is the environment temperature in the second preset cement warehouse, B3 is the environment temperature in the third preset cement warehouse, B4 is the environment temperature in the fourth preset cement warehouse, and B1 is more than 18 ℃ and more than B2, more than B3 and more than B4 and more than 22 ℃; setting K0 (K01, K02, K03, K04) for a matrix K0 of the number of bagged cements stored in the preset cement warehouse, wherein K01 is the number of the bagged cements in the first preset cement warehouse, K02 is the number of the bagged cements in the second preset cement warehouse, K03 is the number of the bagged cements in the third preset cement warehouse, K04 is the number of the bagged cements in the fourth preset cement warehouse, and K01 is more than K02 and is more than K03 and is more than K04;

the data processing module is further used for selecting a corresponding environment temperature as the environment temperature in the cement warehouse according to the relation between Q and the number matrix K0 of the bagged cement in the preset cement warehouse, and cooling the cement warehouse through an air conditioner;

5. The supervision system for a cement warehouse according to claim 4, characterized in that,

the data processing module is further used for calculating the ratio Y of the quantity E of the bagged cement in each region of the six regions to the quantity Q of the bagged cement in the cement warehouse in real time, and the ratio Y is E/Q;

the data processing module is further used for setting a bagged cement quantity ratio matrix G in a preset area and an environment temperature correction coefficient matrix e in a preset cement warehouse, and for the bagged cement quantity ratio matrix G in the preset area, setting G (G1, G2, G3, G4), wherein G1 is the bagged cement quantity ratio in the first preset area, G2 is the bagged cement quantity ratio in the second preset area, G3 is the bagged cement quantity ratio in the third preset area, G4 is the bagged cement quantity ratio in the fourth preset area, and G1 is more than or equal to 0, G2 is more than or equal to G3, G4 is more than or equal to 1/6; setting e (e 1, e2, e3, e 4) for the environment temperature correction coefficient matrix e in the preset cement warehouse, wherein e1 is the environment temperature correction coefficient in the first preset cement warehouse, e2 is the environment temperature correction coefficient in the second preset cement warehouse, e3 is the environment temperature correction coefficient in the third preset cement warehouse, e4 is the environment temperature correction coefficient in the fourth preset cement warehouse, and e1 is more than 0.8, more than e2, more than e3, more than e4, and less than 1.2;

6. A method of supervising a cement warehouse, which evenly divides the interior of the cement warehouse into six zones, comprising:

acquiring the parameter information outside the cement warehouse in real time, wherein the parameter information outside the warehouse comprises the ambient humidity U0 outside the cement warehouse and the ambient temperature P0 outside the cement warehouse;

7. The method of supervising a cement warehouse as claimed in claim 6,

presetting the environmental humidity W01 in a first preset cement warehouse, the environmental humidity W02 in a second preset cement warehouse, the environmental humidity W03 in a third preset cement warehouse and the environmental humidity W04 in a fourth preset cement warehouse, wherein W01 is more than 50 percent and W02 is more than W03 is more than 70 percent; presetting an absolute value S1 of a first preset height change value, an absolute value S2 of a second preset height change value, an absolute value S3 of a third preset height change value and an absolute value S4 of a fourth preset height change value, wherein S1 is more than 0 and more than S2 and more than S3 and more than S4 is less than or equal to 10;

when the height value H0 of the bagged cement is increased, selecting the corresponding environmental humidity in the preset cement warehouse as the environmental humidity in the cement warehouse according to the relation between the Delta S and the absolute value S1 of the first preset height change value, the absolute value S2 of the second preset height change value, the absolute value S3 of the third preset height change value and the absolute value S4 of the fourth preset height change value;

8. The method of supervising a cement warehouse as recited in claim 7,

after the in-warehouse parameter information and the out-warehouse parameter information are obtained, calculating a difference value X between the environmental humidity W0 in the cement warehouse and the environmental humidity U0 outside the cement warehouse, wherein the difference value X = W0-U0;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, when the M01 is larger than or equal to X and is smaller than M02, selecting an environmental humidity correction coefficient A3 in the third preset cement warehouse to correct the environmental humidity W02 in the second preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A3W 02;

when the height value H0 of the bagged cement is increased and the difference value X is larger than 0, when the M02 is larger than or equal to X and smaller than M03, selecting an environmental humidity correction coefficient A2 in the second preset cement warehouse to correct the environmental humidity W03 in the third preset cement warehouse, wherein the corrected environmental humidity in the cement warehouse is A2X W03;

9. The method of supervising a cement warehouse as recited in claim 6,

presetting a quantity matrix K0 of bagged cement stored in a preset cement warehouse and an environment temperature matrix B in the preset cement warehouse, and setting B (B1, B2, B3, B4) for the environment temperature matrix B in the preset cement warehouse, wherein B1 is the environment temperature in the first preset cement warehouse, B2 is the environment temperature in the second preset cement warehouse, B3 is the environment temperature in the third preset cement warehouse, B4 is the environment temperature in the fourth preset cement warehouse, and B1 is more than 18 ℃ and more than B2, and B3 is more than B4 and less than 22 ℃; setting K0 (K01, K02, K03, K04) for a matrix K0 of the number of bagged cement stored in the preset cement warehouse, wherein K01 is the number of the bagged cement in the first preset cement warehouse, K02 is the number of the bagged cement in the second preset cement warehouse, K03 is the number of the bagged cement in the third preset cement warehouse, K04 is the number of the bagged cement in the fourth preset cement warehouse, and K01 < K02 < K03 < K04;

10. The method of supervising a cement warehouse as recited in claim 9,

calculating the ratio Y of the quantity E of bagged cement in each region of the six regions to the quantity Q of the bagged cement in the cement warehouse in real time, wherein the ratio Y is E/Q;

presetting a bagged cement quantity ratio matrix G in a preset area and an environment temperature correction coefficient matrix e in a preset cement warehouse, and setting G (G1, G2, G3 and G4) for the bagged cement quantity ratio matrix G in the preset area, wherein G1 is the bagged cement quantity ratio in a first preset area, G2 is the bagged cement quantity ratio in a second preset area, G3 is the bagged cement quantity ratio in a third preset area, G4 is the bagged cement quantity ratio in a fourth preset area, and G1 is more than or equal to 0 and more than G2 and more than G3 and less than or equal to 1/6; setting e (e 1, e2, e3, e 4) for the environment temperature correction coefficient matrix e in the preset cement warehouse, wherein e1 is the environment temperature correction coefficient in the first preset cement warehouse, e2 is the environment temperature correction coefficient in the second preset cement warehouse, e3 is the environment temperature correction coefficient in the third preset cement warehouse, e4 is the environment temperature correction coefficient in the fourth preset cement warehouse, and e1 is more than 0.8 and less than e2 and less than e3 and less than e4 and less than 1.2;