Disclosure of Invention
The invention aims to provide an anti-wrinkle whitening essence production system, which is used for solving the problems of high construction investment of constant-temperature plants, waste of power resources and environmental pollution in the existing production line.
The purpose of the invention can be realized by the following technical scheme:
an anti-wrinkle whitening essence production system comprises an acquisition module, a control module and an implementation module;
the acquisition module is used for acquiring video data of an anti-wrinkle whitening essence production workshop;
the control module is set to simulate the production temperature of an anti-wrinkle whitening essence production workshop;
the realization module is set to realize the production temperature generated by the management and control module.
Further, the control module comprises a temperature imitation model;
the temperature imitation measurement model comprises an acquisition layer, an arrangement layer, a coefficient layer and a prediction layer;
the acquisition layer is used for acquiring a BIM model of an anti-wrinkle whitening essence production workshop;
the arrangement layer is used for acquiring coordinates of temperature equipment in the BIM model and arranging the temperature equipment to obtain an arrangement coefficient of the temperature equipment;
the coefficient layer is used for acquiring an interference coefficient corresponding to the temperature equipment;
the prediction layer is used for integrating the arrangement coefficient of the temperature equipment and the corresponding interference coefficient to generate the predicted temperature of the temperature equipment.
Further, the arrangement layer is used for acquiring coordinates of temperature equipment in the BIM model and arranging the temperature equipment to obtain an arrangement coefficient of the temperature equipment, specifically, acquiring the BIM model of the anti-wrinkle whitening essence production workshop, reading and identifying the property of an article model in the BIM model through character recognition software, marking the article model with the recognition result of the air conditioner as the temperature equipment, and acquiring the coordinates of the temperature equipment;
acquiring boundary coordinates corresponding to production line equipment in the BIM model, and solving a temperature area of the production line model through the boundary coordinates;
when the coordinates of the temperature equipment belong to the temperature area, marking the corresponding temperature equipment as first adjusting equipment, wherein the corresponding arrangement coefficient is K1;
when the coordinate of the temperature equipment and the temperature line of the temperature area are larger than M1, marking the corresponding temperature equipment as second adjusting equipment, wherein the corresponding arrangement coefficient is K2;
and when the temperature line between the coordinate of the temperature equipment and the temperature area is larger than M2, marking the corresponding temperature equipment as third adjusting equipment, wherein the corresponding arrangement coefficient is K3.
Further, the coefficient layer is used for acquiring an interference coefficient corresponding to the temperature device, specifically, acquiring acquired data of the acquisition device, and performing feature identification to obtain a feature result;
the characteristic result in the adjustment interval corresponding to the adjustment device is the corresponding interference coefficient, wherein the adjustment device specifically comprises a first adjustment device, a second adjustment device and a third adjustment device;
the adjustment intervals are specifically a first adjustment interval, a second adjustment interval and a third adjustment interval;
the first adjusting device corresponds to a first adjusting interval; the second adjusting device corresponds to the second adjusting interval; the third adjustment device corresponds to a third adjustment interval.
Further, the prediction layer is configured to integrate the arrangement coefficient of the temperature device and the corresponding interference coefficient to generate a predicted temperature of the temperature device, specifically, obtain the predicted temperature of the temperature device through a prediction expression;
the prediction expression is as follows: predicted temperature = production temperature × array coefficient × interference coefficient.
Further, the boundary coordinates corresponding to the production line equipment, specifically,
reading and identifying the attribute of the object model in the BIM through character identification software, and marking the identification result as the object model of the production line as production line equipment;
acquiring a plane position coordinate corresponding to production line equipment, wherein the plane position coordinate is (X, Y); x is a plane abscissa corresponding to the production line equipment, and Y is a plane ordinate corresponding to the production line equipment;
generating a boundary auxiliary line of a plane position coordinate, specifically, making a vertical ray along a plane abscissa corresponding to production line equipment to obtain an abscissa auxiliary line; making a vertical ray along a vertical coordinate of a plane corresponding to the production line equipment to obtain a vertical coordinate auxiliary line;
selecting coincident points of the ordinate auxiliary line and the abscissa auxiliary line as boundary coordinates, wherein after coincident points are generated on one side of the ordinate auxiliary line and one side of the abscissa auxiliary line, a plurality of coincident points are provided, and at the moment, selecting the coincident point closest to the plane position coordinate as the boundary coordinate;
and the area enclosed by the boundary coordinates after end-to-end connection is the temperature area.
Further, the temperature line is specifically to obtain a coordinate of the temperature device, specifically, the coordinate of the temperature device is a three-dimensional coordinate, and (X1, Y1, Z1) of the coordinate of the temperature device under the three-dimensional coordinate is selected, where X1 is a three-dimensional abscissa of the temperature device, Y1 is a three-dimensional ordinate of the temperature device, and Z1 is a three-dimensional height coordinate of the temperature device;
making temperature rays along a direction vertical to a three-dimensional abscissa X1 and a direction vertical to a three-dimensional ordinate Y1;
marking the position where the temperature ray is overlapped with the temperature area as a temperature point, and taking a straight line connecting the temperature point and the three-dimensional height coordinate Z1 as a temperature line;
specifically, when the two-dimensional projection of the temperature ray coincides with the temperature region, the temperature ray is considered to coincide with the temperature region.
Further, the characteristic identification is specifically people number identification;
the characteristic result is specifically the product of the person number identification result and the temperature proportional coefficient of the adjustment interval.
Further, the acquisition module comprises a plurality of video acquisition units, and the acquisition module acquires data, specifically, real-time video monitoring files.
Further, the implementation module is specifically a control terminal, configured to obtain a predicted temperature of the temperature device, and control the temperature device.
Compared with the prior art, the invention has the beneficial effects that:
according to the method, the video information in the anti-wrinkle whitening essence production workshop is collected, the video information is analyzed in real time, the interference coefficient of the air conditioner is changed in real time, the temperature influence on a production line caused by crowd gathering is avoided, meanwhile, due to the fact that dresses in summer and autumn and spring and winter are different, the thermal radiation factors of a human body to the surrounding environment are different, and different interference coefficient tables are adopted, so that the temperature of the air conditioner is adjusted more accurately, the temperature constancy of the production line is achieved, and construction resources are saved.
Detailed Description
In order to make 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 of the embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.
Thus, the detailed description of the embodiments of the present invention provided in the following drawings is not intended to limit the scope of the invention as claimed, but is merely representative of selected embodiments of the invention.
As shown in fig. 1, a system for producing anti-wrinkle whitening essence comprises an acquisition module, a control module and an implementation module;
the acquisition module is used for acquiring video data of an anti-wrinkle whitening essence production workshop;
the control module is set to simulate the production temperature of an anti-wrinkle whitening essence production workshop;
and the realization module is set to realize the production temperature generated by the management and control module.
The present application will be explained in detail with reference to specific embodiments;
when the method is implemented, a plurality of video acquisition units are arranged in an anti-wrinkle whitening essence production workshop, and the video acquisition units jointly form an acquisition module for acquiring acquired data; in specific implementation, the video acquisition unit is a high-speed high-definition industrial camera;
the high-speed high-definition industrial camera is specifically installed corresponding to the adjusting interval, the adjusting interval can be monitored completely, the high-speed high-definition industrial camera in the corresponding adjusting interval only collects video monitoring files in the corresponding adjusting interval, the technology is mature, and the application does not specifically limit the video monitoring files in the corresponding adjusting interval to the collection of the high-speed high-definition industrial camera.
A temperature imitation measurement model is arranged in the control module;
in specific implementation, the management and control module can be arranged in any computer; the temperature imitation measurement model comprises an acquisition layer, an arrangement layer, a coefficient layer and a prediction layer; the acquisition layer is used for acquiring a BIM model of an anti-wrinkle whitening essence production workshop;
specifically, a BIM model of an anti-wrinkle whitening essence production workshop is provided for enterprise construction companies, and the BIM model is a common means in the construction industry,
The arrangement layer is used for acquiring coordinates of temperature equipment in the BIM model and arranging the temperature equipment to obtain an arrangement coefficient of the temperature equipment;
specifically, a BIM model of an anti-wrinkle whitening essence production workshop is obtained, the attributes of an article model in the BIM model are read and identified through character identification software, the article model with the air conditioner as an identification result is marked as temperature equipment, and the coordinates of the temperature equipment are obtained;
more specifically, reading and identifying the attribute of the object model in the BIM through character identification software, and marking the identification result as the object model of the production line as production line equipment;
the attribute of the article model is a text marked in the software by the article during modeling;
the character recognition software may be a message flight recognition software, a dog search file recognition software, a Baidu recognition software, etc., and the character recognition technology is a common technology, and the invention is not limited to the character recognition software.
Acquiring a plane position coordinate corresponding to the production line equipment, wherein the plane position coordinate is (X, Y); x is a plane abscissa corresponding to the production line equipment, and Y is a plane ordinate corresponding to the production line equipment;
when needing to pay attention to here, the production line equipment in the BIM model corresponds to the space model, and the plane position coordinate of production line equipment is selected for use in this application, both when specifically realizing, need convert the space coordinate that production line equipment corresponds into plane position coordinate.
As shown in fig. 2, a boundary auxiliary line of the plane position coordinate is generated, specifically, a vertical ray is taken along a plane abscissa corresponding to the production line device, so as to obtain an abscissa auxiliary line; making a vertical ray along a vertical coordinate of a plane corresponding to the production line equipment to obtain a vertical coordinate auxiliary line;
selecting coincident points of the ordinate auxiliary line and the abscissa auxiliary line as boundary coordinates, wherein after coincident points are generated on one side of the ordinate auxiliary line and one side of the abscissa auxiliary line, a plurality of coincident points are provided, and at the moment, selecting coincident points closest to the plane position coordinates as boundary coordinates;
it should be noted here that the boundary coordinates are obtained by interleaving a plurality of boundary auxiliary lines, wherein the boundary auxiliary lines do not include the X-axis and the Y-axis, i.e., the boundary coordinates do not appear on the X-axis and the Y-axis, and do not appear on the coordinate axes.
Acquiring boundary coordinates corresponding to production line equipment in the BIM model, and solving a temperature area of the production line model through the boundary coordinates;
as shown in fig. 3, in the implementation, the temperature region is defined as a region surrounded by the end-to-end boundary coordinates.
When the coordinates of the temperature equipment belong to the temperature area, marking the corresponding temperature equipment as first adjusting equipment, wherein the corresponding arrangement coefficient is K1;
when the coordinate of the temperature equipment and the temperature line of the temperature area are larger than M1, marking the corresponding temperature equipment as second adjusting equipment, wherein the corresponding arrangement coefficient is K2;
when the temperature line between the coordinate of the temperature device and the temperature area is larger than M2, the corresponding temperature device is marked as a third adjusting device, and the corresponding arrangement coefficient is K3.
More specifically, K1 is equal to 1, K2 is 1.4, and K3 is any natural number between 1.4 and 2.
As shown in fig. 4, in a more specific implementation, the temperature line is to obtain coordinates of the temperature device, the coordinates of the temperature device are three-dimensional coordinates, and (X1, Y1, Z1) of the coordinates of the temperature device under the three-dimensional coordinates is selected, where X1 is a three-dimensional abscissa of the temperature device, Y1 is a three-dimensional ordinate of the temperature device, and Z1 is a three-dimensional height coordinate of the temperature device;
the temperature radiation is taken in a direction perpendicular to the three-dimensional abscissa X1 and perpendicular to the three-dimensional ordinate Y1, wherein the starting point of the radiation is the position of the three-dimensional abscissa within the coordinate system, as shown in fig. 4.
Marking the position where the temperature ray is superposed with the temperature area as a temperature point, and taking a straight line connecting the temperature point and the three-dimensional height coordinate Z1 as a temperature line;
the coincidence of the temperature ray with the temperature region is specifically considered to be the coincidence of the temperature ray with the temperature region when the two-dimensional projection of the temperature ray coincides with the temperature region.
The coefficient layer is used for acquiring an interference coefficient corresponding to the temperature equipment;
specifically, acquiring data acquired by acquisition equipment, and performing feature identification to obtain a feature result;
in another embodiment, the feature recognition is specifically a person number recognition.
The characteristic result is specifically the product of the person number identification result and the temperature proportional coefficient of the adjustment interval.
More specifically, the temperature scaling factors are shown in tables one and two, specifically, table one is used in the first quarter and the fourth quarter of the year, and table two is used in the second quarter and the third quarter of the year;
table-by-table quarterly temp. proportional coefficient table
Temperature ratio coefficient table for two, three and four seasons
The characteristic result in the adjustment interval corresponding to the adjustment device is the corresponding interference coefficient, wherein the adjustment device specifically comprises a first adjustment device, a second adjustment device and a third adjustment device;
the adjusting interval is specifically a first adjusting interval, a second adjusting interval and a third adjusting interval;
the first adjusting device corresponds to the first adjusting interval; the second adjusting device corresponds to the second adjusting interval; the third adjustment device corresponds to a third adjustment interval.
In specific implementation, coordinate points corresponding to the adjusting equipment are connected, and the surrounded area is an adjusting interval.
The prediction layer is used for integrating the arrangement coefficient of the temperature equipment and the corresponding interference coefficient to generate the predicted temperature of the temperature equipment;
specifically, the predicted temperature of the temperature equipment is obtained through a prediction expression;
the prediction expression is: predicted temperature = production temperature × array coefficient × interference coefficient.
In some embodiments, the interference coefficient is determined by
In specific implementation, the implementation module, specifically, the control terminal is configured to obtain the predicted temperature of the temperature device and control the temperature device.
More specifically, the control terminal may be a computer or a mobile phone, and the present application does not specifically require this.
The above formulas are all calculated by removing dimensions and taking values thereof, the formula is a formula for obtaining the latest real situation by collecting a large amount of data and carrying out software simulation, and the preset parameters in the formula are set by the technical personnel in the field according to the actual situation.
In the embodiments provided in the present invention, it should be understood that the disclosed apparatus, device and method may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, the division of the modules is only one logical functional division, and there may be other divisions when the actual implementation is performed; the modules described as separate parts may or may not be physically separate, and parts displayed as modules may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the method of the embodiment.
It will also be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof.
The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference signs in the claims shall not be construed as limiting the claim concerned.
Furthermore, it is obvious that the word "comprising" does not exclude other elements or steps, and the singular does not exclude the plural. A plurality of units or means recited in the system claims may also be implemented by one unit or means in software or hardware. The terms second, etc. are used to denote names, but not to denote any particular order.
Finally, it should be noted that the above examples are only intended to illustrate the technical process of the present invention and not to limit the same, and although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical process of the present invention without departing from the spirit and scope of the technical process of the present invention.