CN113342088A - Temperature control cloud platform and interface setting method of user side - Google Patents

Abstract

The invention discloses a temperature control cloud platform and an interface setting method of a user side, and solves the technical problem that concrete, particularly super-large-volume self-compacting concrete, is easy to crack due to large temperature difference in the prior art. The temperature control cloud platform comprises a receiving module, a processing module and a control module, wherein the receiving module is used for receiving the external temperature data of the concrete and the internal temperature data of the warm concrete transmitted by the field equipment; the processing module is used for judging the size relation between the difference value of the external temperature data of the concrete and the internal temperature data of the warm concrete and the first temperature difference threshold value; the sending module is used for sending a water spraying starting instruction to the field equipment when the difference value between the external temperature data of the concrete and the internal temperature data of the warm concrete is larger than or equal to a first temperature difference threshold value; the field device includes: the temperature detection assembly is used for acquiring external temperature data of the concrete and internal temperature data of the warm concrete; the water spraying assembly is used for spraying water to the concrete to cool; and the data transmission equipment is used for communicating with the temperature control cloud platform and is provided with a plurality of interfaces.

Description

Temperature control cloud platform and interface setting method of user side

Technical Field

The invention relates to the technical field of concrete temperature control, in particular to a temperature control cloud platform and an interface setting method of a user side.

Background

After concrete is poured, when the difference between the internal temperature and the external temperature of the concrete is high, the concrete is easy to crack due to the high temperature difference. Through testing the temperature of concrete, adopt cold water to spray the cooling when the temperature is too high, can avoid the concrete fracture at to a great extent.

At present, the temperature control in every district of pouring relies on the artifical management and control of staff in this district of pouring scene, causes the human resource waste to a great extent. For a large-volume pouring area, the technical problems of local cracking caused by incomplete temperature control and water resource waste caused by integral spraying are easy to occur.

Disclosure of Invention

The invention mainly aims to provide a temperature control cloud platform and an interface setting method of a user side, and aims to solve the technical problem that concrete, especially super-large-volume self-compacting concrete, is easy to crack due to large temperature difference in the prior art.

To achieve the above object, according to one aspect of the present invention, a temperature controlled cloud platform is provided. The technical scheme is as follows:

the temperature control cloud platform is used for processing concrete temperature data and comprises a receiving module used for receiving the concrete external temperature data and the temperature data in the concrete transmitted by the field equipment; the processing module is used for judging the size relation between the difference value of the external temperature data of the concrete and the internal temperature data of the warm concrete and the first temperature difference threshold value; the sending module is used for sending a water spraying starting instruction to the field equipment when the difference value between the external temperature data of the concrete and the internal temperature data of the warm concrete is larger than or equal to a first temperature difference threshold value; wherein the field device comprises: the temperature detection assembly is used for acquiring external temperature data of the concrete and internal temperature data of the warm concrete; the water spraying assembly is used for spraying water to the concrete to cool; the data transmission equipment is used for communicating with the temperature control cloud platform and is provided with a plurality of interfaces, and the interfaces are matched with the temperature detection assembly and the water spraying assembly; and the data transmission equipment transmits the concrete external temperature data and the warm concrete internal temperature data to the temperature control cloud platform, and when the difference value between the concrete external temperature data and the warm concrete internal temperature data is larger than or equal to a first temperature difference threshold value, the data transmission equipment receives the instruction of the sending module and starts the water spraying assembly.

The early warning module is used for sending an early warning instruction to a user side and/or on-site warning equipment when the difference value between the concrete external temperature data and the warm concrete internal temperature data is larger than or equal to a second temperature difference threshold value.

Further, the second temperature difference threshold value is larger than the first temperature difference threshold value; and/or when the difference value between the external temperature data of the concrete and the internal temperature data of the warm concrete is larger than or equal to the second temperature difference threshold value, the data transmission equipment receives the instruction of the sending module and starts the water spraying assembly.

Further, the system also comprises a field terminal device and a remote terminal device which are communicated with the temperature control cloud platform.

Furthermore, the temperature detection assembly comprises a room temperature sensor arranged outside the concrete and an internal sensor arranged inside the concrete, and when any one of the length, the width and the height of the concrete is more than or equal to 5 m, at least two internal sensors are uniformly distributed inside the concrete; the water spraying assembly comprises an electromagnetic valve arranged on the water spraying pipe.

The internal sensors are divided into at least two groups in the horizontal direction, the number of the water spraying assemblies is matched with the number of the groups of the internal sensors, and when the difference value between the internal temperature data of the warm concrete and the external temperature data of the concrete detected by any one internal sensor in one group is larger than or equal to a first temperature difference threshold value, the data transmission equipment receives an instruction of the sending module and starts the corresponding water spraying assembly.

In order to achieve the above object, according to another aspect of the present invention, a method for setting an interface of a user side based on the above temperature control cloud platform is also provided. The technical scheme is as follows:

the interface setting method of the user side comprises the following steps: filling basic information of the data transmission equipment in the adding interface of the data transmission equipment and then storing the basic information; the basic information of the data transmission equipment at least comprises an equipment name and an equipment code; filling basic information of the solenoid valve in the solenoid valve adding interface and storing the basic information; the basic information of the electromagnetic valve at least comprises an electromagnetic valve code, an affiliated equipment code and an affiliated equipment interface serial number; filling basic information of the temperature sensor in the temperature sensor adding interface and then storing the basic information; the basic information of the temperature sensor at least comprises whether the room temperature is detected, the code of the equipment and the interface serial number of the equipment.

Further, the method also comprises the following steps: filling basic information of the equipment group in the equipment group adding interface and then storing the basic information; the basic information of the equipment group at least comprises an equipment group name; the basic information of the data transmission device also includes the name of the device group to which it belongs.

Further, the method also comprises the following steps: generating a first table at least displaying start-stop records of the solenoid valve according to the selected solenoid valve in a solenoid valve recording interface; and/or generating a second table at least displaying monitoring records of all temperature sensors corresponding to the data transmission equipment in the temperature recording interface according to the selected data transmission equipment.

Further, the method also comprises the following steps: and generating a change curve of the difference value corresponding to the internal sensor along with time in the temperature recording interface according to the selected internal sensor.

Additional aspects and advantages of embodiments of the inventions provided herein will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of embodiments of the inventions provided herein.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the embodiments of the invention and are not intended to limit the invention.

Fig. 1 is a schematic structural diagram of a first embodiment of a temperature-controlled cloud platform according to the present invention.

FIG. 2 is a schematic diagram of the field distribution of the temperature sensing assembly and the water spray assembly in the field device.

Fig. 3 is a schematic structural diagram of a second embodiment of the temperature-controlled cloud platform according to the present invention.

Fig. 4 is a schematic structural diagram of a third embodiment of the temperature-controlled cloud platform according to the present invention.

The relevant references in the above figures are: 110-receiving module, 120-processing module, 130-sending module, 140-early warning module, 200-temperature detection component, 210-room temperature sensor, 220-internal sensor, 300-water spray component, 310-solenoid valve, 400-data transmission device, 510-remote terminal device, 520-field terminal device, and 600-warning device.

Detailed Description

The embodiments of the invention provided in the present specification will be clearly and completely described below with reference to the accompanying drawings. Those skilled in the art will be able to implement the embodiments of the invention provided in this specification based on these descriptions. Before the embodiments of the invention provided in this specification are explained with reference to the drawings, it is to be noted that:

the technical solutions and the technical features provided in the embodiments of the invention provided in the present specification in each part including the following description may be combined with each other without conflict.

Furthermore, the embodiments of the invention provided in this specification and referred to in the following description are generally only a subset of the embodiments of the invention provided in this specification and not all of them, so that all other embodiments obtained by those skilled in the art without any inventive work based on the embodiments of the invention provided in this specification and referred to in the claims of the invention provided in this specification shall fall within the scope of the protection of the embodiments of the invention provided in this specification.

With respect to the terms and units in the examples of the invention provided in this specification: the terms "comprising," "including," "having," and any variations thereof in the description and claims and associated parts of the embodiments of the invention provided in this specification are intended to cover non-exclusive inclusions. In addition, other related terms and units in the embodiments of the invention provided by the specification can be reasonably interpreted based on the related contents of the embodiments of the invention provided by the specification.

Fig. 1 is a schematic structural diagram of a first embodiment of a temperature-controlled cloud platform according to the present invention.

As shown in fig. 1, the temperature control cloud platform for processing concrete temperature data includes a receiving module 110, a processing module 120, and a transmitting module 130; the system comprises a field device, a data acquisition module, a data processing module and a data processing module, wherein the data acquisition module is used for receiving external concrete temperature data and internal warm concrete temperature data transmitted by the field device; the processing module 120 is configured to determine a magnitude relationship between a difference between the external temperature data of the concrete and the internal temperature data of the warm concrete and a first temperature difference threshold; the sending module 130 is configured to send a water spraying start instruction to the field device when a difference between the external temperature data of the concrete and the internal temperature data of the warm concrete is greater than or equal to a first temperature difference threshold.

The field device includes a temperature detection assembly 200, a water spray assembly 300, and a data transmission device 400; the temperature detection assembly 200 is used for acquiring external temperature data of concrete and internal temperature data of warm concrete; the water spraying assembly 300 is used for spraying water to the concrete to cool; the data transmission device 400 is used for communicating with the temperature control cloud platform, and the data transmission device 400 is provided with a plurality of interfaces which are matched with the temperature detection assembly 200 and the water spray assembly 300; the data transmission device 400 transmits the concrete external temperature data and the warm concrete internal temperature data to the temperature control cloud platform, and when the difference value between the concrete external temperature data and the warm concrete internal temperature data is greater than or equal to the first temperature difference threshold value, the data transmission device 400 receives the instruction of the sending module 130 and starts the water spray assembly 300.

The temperature detection assembly 200 comprises a room temperature sensor 210 arranged outside the concrete and an internal sensor 220 arranged inside the concrete, and the water spray assembly 300 comprises a solenoid valve 310 arranged on a water spray pipe.

FIG. 2 is a schematic diagram of the field distribution of the temperature sensing assembly and the water spray assembly in the field device.

As shown in fig. 2, when any one of the length, the width and the height of the concrete is greater than or equal to 5 m, at least two internal sensors 220 are uniformly distributed in the concrete; for example, when two internal sensors 220 need to be provided in the height direction, the two internal sensors 220 are provided at the bottom and the middle of the concrete.

Further, the internal sensors 220 are divided into at least two groups (four groups in the figure) in the horizontal direction, the number of the water spray assemblies 300 is matched with the number of the groups of the internal sensors 220, and when the difference value between the internal temperature data of the warm concrete detected by any one of the internal sensors 220 in one group and the external temperature data of the concrete is greater than or equal to the first temperature difference threshold value, the data transmission device 400 receives the instruction of the sending module 130 and starts the corresponding water spray assembly 300. Therefore, for the concrete with larger volume, water can be sprayed and cooled by regions, and water resources are saved.

The temperature detection assembly 200 and the water spray assembly 300 are configured according to the number of interfaces of the data transmission apparatus 400, that is, the interfaces of each data transmission apparatus 400 may be all used for installing the temperature detection assembly 200 or the water spray assembly 300, or the detection assembly and the water spray assembly 300 may be installed at the same time.

For concrete with a large volume, especially concrete with a volume of more than or equal to 200 square meters, a plurality of data transmission devices 400 can be configured; when the matched internal sensor 220 and the water spray assembly 300 are not installed on the same data transmission device 400, or the same data transmission device 400 is connected with at least two internal sensors 220 and at least two water spray assemblies 300, the temperature-controlled cloud platform may, but is not limited to, identify the corresponding relationship among the internal sensor 220, the water spray assembly 300 and the data transmission device 400 by encoding.

Fig. 3 is a schematic structural diagram of a second embodiment of the temperature-controlled cloud platform according to the present invention.

As shown in fig. 3, based on the first embodiment, the second embodiment of the temperature-controlled cloud platform for processing concrete temperature data further includes: and the early warning module 140, wherein the early warning module 140 is configured to send an early warning instruction to a user side and/or the field warning device 600 when the difference between the external temperature data of the concrete and the internal temperature data of the warm concrete is greater than or equal to the second temperature difference threshold. At this time, the sending module 130 still sends a water spraying start-stop instruction to the field data transmission device 400; the field device further comprises an alarm device 600, the alarm device 600 being located near the concrete or in a monitoring room, the alarm device 600 preferably being an alarm bell and/or an alarm lamp.

The second temperature difference threshold is larger than the first temperature difference threshold, so that when the difference value between the external temperature data of the concrete and the internal temperature data of the warm concrete is larger than or equal to the second temperature difference threshold, the purpose of cooling the concrete to a safe value cannot be achieved only by spraying water for cooling, and at the moment, related workers can be timely notified to process the concrete in time through early warning.

The manner of sending the warning instruction to the user side may be, but is not limited to, text information, pictures or audio; the field warning device 600 may be, but is not limited to, a bell and/or a warning light remotely controlled by a temperature controlled cloud platform.

Fig. 4 is a schematic structural diagram of a third embodiment of the temperature-controlled cloud platform according to the present invention.

As shown in fig. 4, based on the first or second embodiment, the third embodiment of the temperature-controlled cloud platform for processing concrete temperature data further includes: the field devices further comprise field terminal devices 520 and remote terminal devices 510, the field terminal devices 520 and the remote terminal devices 510 are communicated with the temperature control cloud platform, and on one hand, the field terminal devices 520 and the remote terminal devices 510 can be used for displaying processing results of the cloud platform, and on the other hand, start-stop instructions of the water spray assembly 300 can be sent to the cloud platform.

The first specific implementation manner of the user side interface setting method based on the temperature control cloud platform comprises the following steps:

filling basic information of the data transmission equipment in the adding interface of the data transmission equipment and then storing the basic information; the basic information of the data transmission device mainly includes: the method comprises the following steps of (1) automatically sending a water spraying start-stop instruction, whether the water spraying start-stop instruction is on line, a first temperature difference threshold value, a second temperature difference threshold value, adding time, last on-line time, state (whether normal) and remark information and the like;

basic information of a plurality of data transmission devices is displayed on a data transmission device list interface in a list form; an editing button and a deleting button are arranged in the list, the basic information can be modified after the editing button is clicked, and the deleting button is used for deleting the data transmission equipment of the corresponding column; an adding button is arranged above the list, and an adding interface of the data transmission equipment is generated after the adding button is clicked; an inquiry button and an inquiry column are also arranged above the list, and the required data transmission equipment can be quickly searched by clicking the inquiry button after the basic information is input in the inquiry column;

filling basic information of the solenoid valve in the solenoid valve adding interface and storing the basic information; the basic information of the electromagnetic valve mainly comprises: the method comprises the following steps of (1) obtaining the name of an electromagnetic valve, the code of the electromagnetic valve, the installation position, a switch (namely start-stop state), adding time, a first temperature difference threshold value, the name of an affiliated device, the code of the affiliated device, the serial number of an interface of the affiliated device, the state, remark information and the like;

basic information of a plurality of electromagnetic valves is displayed on an electromagnetic valve list interface in a list form; an 'edit' button and a 'delete' button are arranged in the list, and basic information can be modified after the 'edit' is clicked, wherein the 'delete' button is used for deleting the electromagnetic valves of the corresponding columns; an adding button is arranged above the list, and an electromagnetic valve adding interface is generated after the adding button is clicked; an inquiry button and an inquiry column are also arranged above the list, and the required electromagnetic valve can be quickly searched by clicking the inquiry button after basic information is input in the inquiry column;

filling basic information of the temperature sensor in the temperature sensor adding interface and then storing the basic information; the basic information of the temperature sensor mainly includes: the method comprises the following steps of (1) belonging equipment name, belonging equipment code, belonging equipment interface serial number, temperature sensor name, installation position, adding time, whether room temperature is tested or not, state (whether normal or not), remark information and the like; when the electromagnetic valve and the temperature sensor are installed on different data transmission equipment, in order to enable the temperature control cloud platform to send a water spraying start-stop instruction to correct data transmission equipment, the basic information of the internal sensor further comprises a corresponding electromagnetic valve code;

basic information of a plurality of temperature sensors is displayed on a temperature sensor list interface in a list form; an editing button and a deleting button are arranged in the list, the basic information can be modified after the editing button is clicked, and the deleting button is used for deleting the temperature sensor of the corresponding column; an adding button is arranged above the list, and a temperature sensor adding interface is generated after the adding button is clicked; an inquiry button and an inquiry column are also arranged above the list, and the required temperature sensor can be quickly searched by clicking the inquiry button after basic information is input in the inquiry column;

and generating a first table in an electromagnetic valve recording interface according to the selected electromagnetic valve, wherein the first table displays start-stop records and basic information of the electromagnetic valve, specifically displays information such as names of control personnel, names of affiliated projects, names of affiliated equipment groups, names of affiliated equipment, names of electromagnetic valves, first temperature difference thresholds, switches (namely start-stop states) and uploading time.

Generating a second table in a temperature recording interface according to the selected data transmission equipment, wherein the second table displays monitoring records and basic information of all temperature sensors corresponding to the data transmission equipment, specifically displays information such as an affiliated project name, an affiliated equipment group name, an affiliated equipment name, a temperature sensor name, an installation position, a detected temperature value, a first temperature difference threshold value, reporting time and the like; generating a change curve of the difference value corresponding to the internal sensor along with time in a temperature recording interface according to the selected internal sensor; preferably, the second table and the change curve are displayed on a temperature recording interface for easy viewing.

On the basis of the first embodiment, the second embodiment of the interface setting method of the user side further includes the steps of: filling basic information of the equipment group in the equipment group adding interface and then storing the basic information; the basic information of the device group mainly includes: grouping name, adding time, state (normal or not), belonging project name, remark information and the like; the basic information of the data transmission device also includes the name of the device group to which it belongs. Therefore, when a plurality of concretes need to be subjected to temperature control, and each concrete has a large volume and needs to be provided with a plurality of data transmission devices, the data transmission devices can be grouped to facilitate management and checking; of course, the data transmission devices can also be grouped in other ways, such as grouping the data transmission devices of each floor.

Basic information of a plurality of equipment groups is displayed on an equipment group list interface in a list form; an editing button and a deleting button are arranged in the list, the basic information can be modified after the editing button is clicked, and the deleting button is used for deleting the equipment group of the corresponding column; an adding button is arranged above the list, and an equipment group adding interface is generated after the adding button is clicked; an inquiry button and an inquiry column are arranged above the list, and the required equipment group can be quickly searched by clicking the inquiry button after the basic information is input in the inquiry column.

On the basis of the second embodiment, the third embodiment of the interface setting method of the user side further includes the steps of: filling basic information of the engineering project in an engineering project adding interface and then storing the basic information; the basic information of the engineering project mainly comprises: project name, project address, longitude (the longitude of the geographic coordinate of the project), latitude (the latitude of the geographic coordinate of the project), name of a responsible person, contact telephone of the responsible person, city of the project, project adding time, state (whether the project is started) and remark information; the basic information of the device group also includes the name of the item to which it belongs. Therefore, the operation conditions of each equipment group, the data transmission equipment, the electromagnetic valve and the temperature sensor under the project can be quickly checked in the mode of the engineering project.

Displaying the basic information of a plurality of engineering projects on an engineering project list interface in a list form; an editing button and a deleting button are arranged in the list, the basic information can be modified after the editing button is clicked, and the deleting button is used for deleting the engineering project of the corresponding column; an adding button is arranged above the list, and an engineering project adding interface is generated after the adding button is clicked; and an inquiry button and an inquiry column are arranged above the list, and the required engineering project can be quickly searched by clicking the inquiry button after the basic information is input in the inquiry column.

In addition, for mass concrete or engineering projects with a plurality of data transmission devices, only one room temperature sensor needs to be arranged, and at the moment, the data transmission devices are managed in groups or engineering projects are managed, so that the internal temperature data of the concrete transmitted by other data transmission devices which are not provided with the room temperature sensors in the groups are effectively processed by the processing module of the temperature control cloud platform.

On the basis of the third embodiment, the fourth embodiment of the interface setting method of the user side further includes the steps of: filling basic information of a user in a user adding interface, storing and generating a user registration code; the basic information of the engineering project, the basic information of the equipment group and the basic information of the equipment also comprise user registration codes corresponding to the responsible persons; after the responsible person logs in the user side by adopting the corresponding user registration code, an electromagnetic valve start-stop instruction can be sent to the temperature control cloud platform on the display interface of the user side, and the temperature control cloud platform sends the instruction to the corresponding data transmission equipment.

Some basic information in the basic information needs to be actively input, and some basic information is automatically identified and generated by the input basic information.

The contents of the embodiments of the invention provided in the present specification are explained above. Those skilled in the art will be able to implement the embodiments of the invention provided in this specification based on these descriptions. Based on the above description of the embodiments of the invention provided in this specification, all other preferred embodiments and examples obtained by those skilled in the art without any inventive work should fall within the scope of the protection of the embodiments of the invention provided in this specification.

Claims (10)

1. Temperature control cloud platform for handle concrete temperature data, its characterized in that: comprises that

The receiving module (110) is used for receiving the external temperature data of the concrete and the internal temperature data of the warm concrete transmitted by the field device;

the processing module (120) is used for judging the size relation between the difference value of the concrete external temperature data and the warm concrete internal temperature data and the first temperature difference threshold value;

the sending module (130) is used for sending a water spraying starting instruction to the field equipment when the difference value between the external temperature data of the concrete and the internal temperature data of the warm concrete is larger than or equal to a first temperature difference threshold value;

wherein the field device comprises:

the temperature detection assembly (200) is used for acquiring external temperature data of the concrete and internal temperature data of the warm concrete;

the water spraying assembly (300) is used for spraying water to the concrete to cool;

the data transmission device (400) is used for communicating with the temperature control cloud platform, and the data transmission device (400) is provided with a plurality of interfaces which are matched with the temperature detection assembly (200) and the water spray assembly (300);

the data transmission equipment (400) transmits the concrete external temperature data and the temperature concrete internal temperature data to the temperature control cloud platform, and when the difference value between the concrete external temperature data and the temperature concrete internal temperature data is larger than or equal to a first temperature difference threshold value, the data transmission equipment (400) receives the instruction of the sending module (130) and starts the water spraying assembly (300).

2. The temperature-controlled cloud platform of claim 1, wherein: the early warning system is characterized by further comprising an early warning module (140), wherein the early warning module (140) is used for sending an early warning instruction to a user side and/or a field warning device (600) when the difference value between the concrete external temperature data and the warm concrete internal temperature data is larger than or equal to a second temperature difference threshold value.

3. The temperature-controlled cloud platform of claim 2, wherein: the second temperature difference threshold value is larger than the first temperature difference threshold value; and/or when the difference value between the concrete external temperature data and the warm concrete internal temperature data is larger than or equal to the second temperature difference threshold value, the data transmission equipment (400) receives the instruction of the sending module (130) and starts the water spraying assembly (300).

4. The temperature-controlled cloud platform of claim 1, wherein: the system also comprises a field terminal device (520) and a remote terminal device (510) which are communicated with the temperature control cloud platform.

5. The temperature-controlled cloud platform of claim 1, wherein: the temperature detection assembly (200) comprises a room temperature sensor (210) arranged outside the concrete and an internal sensor (220) arranged inside the concrete, and when any one of the length, the width and the height of the concrete is more than or equal to 5 m, at least two internal sensors (220) are uniformly distributed inside the concrete; the water spray assembly (300) comprises a solenoid valve (310) arranged on a water spray pipe.

6. The temperature-controlled cloud platform of claim 5, wherein: the internal sensors (220) are divided into at least two groups in the horizontal direction, the number of the water spraying assemblies (300) is matched with the number of the groups of the internal sensors (220), and when the difference value between the internal temperature data of the warm concrete detected by any one internal sensor (220) in one group and the external temperature data of the concrete is larger than or equal to a first temperature difference threshold value, the data transmission equipment (400) receives an instruction of the sending module (130) and starts the corresponding water spraying assembly (300).

7. The interface setting method for the user side of the temperature control cloud platform according to any one of claims 1 to 6, comprising: the method comprises the following steps:

filling basic information of the data transmission equipment in the adding interface of the data transmission equipment and then storing the basic information; the basic information of the data transmission equipment at least comprises an equipment name and an equipment code;

filling basic information of the solenoid valve in the solenoid valve adding interface and storing the basic information; the basic information of the electromagnetic valve at least comprises an electromagnetic valve code, an affiliated equipment code and an affiliated equipment interface serial number;

filling basic information of the temperature sensor in the temperature sensor adding interface and then storing the basic information; the basic information of the temperature sensor at least comprises whether the room temperature is detected, the code of the equipment and the interface serial number of the equipment.

8. The interface setting method as claimed in claim 7, wherein: further comprising the steps of: filling basic information of the equipment group in the equipment group adding interface and then storing the basic information; the basic information of the equipment group at least comprises an equipment group name; the basic information of the data transmission device also includes the name of the device group to which it belongs.

9. The interface setting method as claimed in claim 7, wherein: further comprising the steps of:

generating a first table at least displaying start-stop records of the solenoid valve according to the selected solenoid valve in a solenoid valve recording interface; and/or the like and/or,

and generating a second table at least displaying monitoring records of all temperature sensors corresponding to the data transmission equipment in the temperature recording interface according to the selected data transmission equipment.

10. The interface setting method as claimed in claim 8, wherein: further comprising the steps of: and generating a change curve of the difference value corresponding to the internal sensor along with time in the temperature recording interface according to the selected internal sensor.

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