CN213843813U - Energy-saving environment-friendly intelligent system for curing paint - Google Patents

Abstract

The utility model discloses an energy-concerving and environment-protective intelligent system for paint coating solidification, including the high in the clouds, the high in the clouds passes through wiFi module, bluetooth module and ethernet and is connected with the ARM treater, the ARM treater still is connected with human-computer interaction, external control signal and optoelectronic isolation high-speed CAN bus interface respectively. The energy-saving environment-friendly intelligent system for curing the paint coating loads the LEDN module in a communication mode of a photoelectric isolation high-speed CAN bus interface, and CAN realize the control of 185KW level with super-high power; the ultraviolet LED technology replaces a mercury lamp, so that the electricity cost is greatly saved, and no pollution is caused; an intelligent system combined with big data is adopted to control the LEDN module; the intelligent control system integrating energy conservation, environmental protection and intelligence helps a factory to realize the intellectualization of equipment, production and service.

Description

Energy-saving environment-friendly intelligent system for curing paint

Technical Field

The utility model relates to a fitment technical field specifically is an energy-concerving and environment-protective intelligent system for paint coating solidification.

Background

The home decoration is to 'materialize' various situations of life into a room, the structural design of a common room is already finished and cannot be greatly adjusted, so that the remaining movable parts are decoration points. Because the life is self, the self must intervene in the decoration process, not only during the decoration design and construction, but also for a long time, and the improvement is continuous after the people live in. Decoration is a huge and trivial project, and the process is performed no matter how large the decoration is to the customization of floors and furniture or the purchase of a plurality of screws; the coordination work of multiple industries such as small as organizing water and electricity, carpenters and the like needs to be integrated by the owners with intelligence, and is a thing which is eager and hard. The most popular home decoration concept of heavy decoration and light decoration at present has the greatest characteristics of saving money, short decoration time and environmental protection, and many owners can select DIY decoration to decorate the ID style of the owners.

At present, the home decoration market adopts a solvent type thermosetting coating, a large amount of VOC (volatile organic compounds) is discharged when the coating is cured by a mercury lamp, the environment is polluted, the environmental pollution can not reach the environmental evaluation standard, and a large amount of waste mercury lamps are generated every year to cause mercury pollution; mercury lamps cannot be electronically controlled; the irradiation surface required by coating curing is large (usually between 1 and 2 meters), the light-emitting energy requirement reaches more than 15W/CM2, so the total electric power is usually more than 20KW, and no ultraviolet LED for coating curing exists in the market at present; the LED control does not adopt an intelligent control system combined with big data, and does not adopt a high-speed CAN to load the LED to realize the control of super-high power.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an energy-concerving and environment-protective intelligent system for paint coating solidification to it is solvent type thermosetting coating to put forward in the present house ornamentation market among the above-mentioned background art and put forward, can produce a large amount of VOC and discharge with the mercury lamp solidification, the polluted environment, can not reach the critique standard, and produce a large amount of mercury lamps of reporting to the public at every year and can cause mercury pollution; mercury lamps cannot be electronically controlled; the irradiation surface required by coating curing is large, the light-emitting energy requirement reaches more than 15W/CM2, so the total electric power is usually more than 20KW, and no ultraviolet LED for coating curing exists in the current market; the LED control does not adopt an intelligent control system combined with big data, and the problem of realizing the control of super-high power by loading the LED by a high-speed CAN is solved.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an energy-concerving and environment-protective intelligent system for paint coating solidification, the high in the clouds passes through wiFi module, bluetooth module and ethernet and is connected with the ARM treater, the ARM treater still is connected with human-computer interaction, external control signal and optoelectronic isolation high-speed CAN bus interface respectively.

Preferably, the cloud end forms communication connection with the WiFi module and the Bluetooth module respectively; the cloud end is further electrically connected with the Ethernet in a bidirectional mode through a conducting wire.

Preferably, the WiFi module and the Bluetooth module are electrically connected with the ARM processor in a bidirectional parallel mode through wires.

Preferably, the ARM processor is respectively electrically connected with the human-computer interaction interface, the external control signal interface and the photoelectric isolation high-speed CAN bus interface in a bidirectional parallel mode through wires.

Preferably, the output end of the photoelectric isolation high-speed CAN bus interface is connected with a CAN controller, the output end of the CAN controller is connected with a site N processor, the input end of the site N processor is respectively connected with a voltage current acquisition circuit, an LED temperature acquisition control current circuit and a constant current driving circuit, and the output end of the constant current driving circuit is connected with an LEDN module.

Preferably, the photoelectric isolation high-speed CAN bus interface forms a bidirectional parallel electric connection with the CAN controller through a wire, the CAN controller forms a bidirectional parallel electric connection with the site N processor through a wire, the site N processor forms a unidirectional series electric connection with the voltage current acquisition and the LED temperature acquisition control current respectively through a wire, the site N processor forms a bidirectional parallel electric connection with the constant current driving circuit through a wire, and the constant current driving circuit forms a unidirectional series electric connection with the LEDN module through a wire.

Preferably, N in the site N processor and the LEDN module is a natural number.

Compared with the prior art, the beneficial effects of the utility model are as follows:

the utility model is provided with a WiFi module, a Bluetooth module, an Ethernet and an ARM processor, and can effectively provide a connection mode for data transmission of the cloud end through the WiFi module, the Bluetooth module and the Ethernet; data information interaction can be effectively realized through the WiFi module, the Bluetooth module and the Ethernet, control information can be transmitted to the ARM processor, the ARM processor can feed back data information to the cloud end, the running condition can be known in time, the WiFi module and the Bluetooth module can transmit LED running data to the cloud end or share the LED running data with other equipment to realize data or signals, and meanwhile, remote control and monitoring can be received, so that intelligent production is realized;

the utility model discloses be provided with human-computer interaction, external control signal and optoelectronic isolation high-speed CAN bus interface, CAN control external control signal and optoelectronic isolation high-speed CAN bus interface through the ARM treater to and CAN feed back data message to human-computer interaction, external control signal and optoelectronic isolation high-speed CAN bus interface, thereby CAN effectively realize remote monitoring, discover the abnormal situation of operation as early as possible and CAN inform the user to use unusually in the very first time; and remote updating of the software program, networking communication with other surrounding equipment and data transmission to the cloud end are realized, so that data sharing and remote control are realized. And the human-computer interaction can adjust system parameters, set working parameters and monitor the running state.

The utility model adopts the communication mode of the photoelectric isolation high-speed CAN bus interface to load the LEDN module, thereby realizing the 185 KW-level control of the super-large power; the ultraviolet LED technology replaces a mercury lamp, so that the electricity cost is greatly saved, and no pollution is caused; an intelligent system combined with big data is adopted to control the LEDN module; the intelligent control system integrates energy conservation, environmental protection and intelligence, helps a factory to realize the intellectualization of equipment, production and service, and is real intelligent production.

Drawings

FIG. 1 is a schematic view of the structure of the present invention;

fig. 2 is a control schematic diagram of the LED lamp set of the present invention.

In the figure: 1. a cloud end; 2. a WiFi module; 3. a Bluetooth module; 4. an ARM processor; 5. performing human-computer interaction; 6. an Ethernet; 7. an external control signal; 8. and the photoelectric isolation high-speed CAN bus interface.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1, the utility model provides a technical solution: the utility model provides an energy-concerving and environment-protective intelligent system for paint coating solidification, includes high in the clouds 1, and high in the clouds 1 passes through wiFi module 2, bluetooth module 3 and ethernet 6 to be connected with ARM treater 4, and ARM treater 4 still is connected with human-computer interaction 5, external control signal 7 and optoelectronic isolation high-speed CAN bus interface 8 respectively.

The utility model discloses in: the cloud 1 is in communication connection with the WiFi module 2 and the Bluetooth module respectively; the cloud 1 is also electrically connected with the ethernet 6 in a bidirectional manner through a wire. Wherein, the communication connection can be for wireless communication such as router communication, the utility model discloses do not do the restriction to this, high in the clouds 1 can be connected with ethernet 6 through the anchor, and effectual data transmission for high in the clouds 1 provides connected mode.

The utility model discloses in: the WiFi module 2 and the Bluetooth module 3 are electrically connected with the ARM processor 4 in a bidirectional parallel mode through wires; can effectual realization data information interaction through wiFi module 2 and bluetooth module 3, can transmit control information to ARM treater 4 to and ARM treater 4 can feed back data information to high in the clouds 1, can in time know the behavior, wiFi module 2 and bluetooth module 3 can realize data or signal sharing with LED operation data conveying to high in the clouds 1 or other equipment, also can accept remote control and control simultaneously, realize intelligent production.

As shown in fig. 2, in the present invention: the ARM processor 4 is respectively electrically connected with the human-computer interaction 5, the external control signal 7 and the photoelectric isolation high-speed CAN bus interface 8 in a bidirectional parallel mode through leads; human-computer interaction 5 accessible ARM treater 4 steerable external control signal 7 and optoelectronic isolation high-speed CAN bus interface 8, and CAN feed back data message to human-computer interaction 5, external control signal 7 and optoelectronic isolation high-speed CAN bus interface 8, thereby CAN effectually realize remote monitoring discovers the abnormal operation situation as early as possible and CAN inform the user at the very first time to use unusually, and the remote updating of software program, CAN be with other equipment network communication on every side simultaneously, also CAN convey data to high in the clouds 1, realize data sharing and remote control, and human-computer interaction 5 adjustable system parameter, the settlement of working parameter, and the control of running state.

The utility model discloses in: the output end of the photoelectric isolation high-speed CAN bus interface 8 is connected with a CAN controller, the output end of the CAN controller is connected with a site N processor, the input end of the site N processor is respectively connected with a voltage current acquisition circuit, an LED temperature acquisition control current circuit and a constant current driving circuit, and the output end of the constant current driving circuit is connected with an LEDN module.

The utility model discloses in, adopt the mercury lamp among the ultraviolet LED technique to replace prior art, the contrast of mercury lamp and LED banks is as shown in the following table:

the utility model discloses in: the photoelectric isolation high-speed CAN bus interface 8 is in bidirectional parallel electric connection with the CAN controller through a wire, the CAN controller is in bidirectional parallel electric connection with the site N processor through a wire, the site N processor is in unidirectional series electric connection with voltage current acquisition and LED temperature acquisition control current through wires, the site N processor is in bidirectional parallel electric connection with the constant current driving circuit through a wire, and the constant current driving circuit is in unidirectional series electric connection with the LEDN module through a wire. And the LEDN module is loaded by adopting a communication mode of the photoelectric isolation high-speed CAN bus interface 8, so that the control of 185KW level with super-large power CAN be realized.

The utility model discloses in: n in the site N processor and the LEDN module is a natural number, and N can be any natural number such as 1, 2, 3 and the like.

The working principle of the energy-saving environment-friendly intelligent system for curing the paint coating is as follows: firstly, the cloud end 1 transmits data to the ARM processor 4 or receives data of the ARM processor 4 through at least one of the WiFi module 2, the Bluetooth module 3 and the Ethernet, the ARM processor 4 is respectively electrically connected with the human-computer interaction 5, the external control signal 7 and the photoelectric isolation high-speed CAN bus interface 8 in a bidirectional parallel mode through wires, and CAN feed back data information to the human-computer interaction 5, an external control signal 7 and a photoelectric isolation high-speed CAN bus interface 8, the human-computer interaction 5 CAN adjust system parameters, set working parameters, monitor the running state and remotely update software programs, meanwhile, the system can be communicated with other surrounding devices in a networking way, and can also transmit data to the cloud end 1 to realize data sharing and remote control, then, a LEDN module is loaded by adopting a communication mode of the photoelectric isolation high-speed CAN bus interface 8, and the control of 185KW level with super-large power CAN be realized.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an energy-concerving and environment-protective intelligent system for paint coating solidification, includes high in the clouds (1), its characterized in that: the cloud end (1) is connected with the ARM processor (4) through the WiFi module (2), the Bluetooth module (3) and the Ethernet (6), and the ARM processor (4) is further connected with a human-computer interaction (5), an external control signal (7) and a photoelectric isolation high-speed CAN bus interface (8) respectively.

2. The energy-saving environment-friendly intelligent system for paint coating curing according to claim 1, characterized in that: the cloud (1) is in communication connection with the WiFi module (2) and the Bluetooth module respectively; the cloud end (1) is also electrically connected with the Ethernet (6) in a bidirectional mode through a wire.

3. The energy-saving environment-friendly intelligent system for paint coating curing according to claim 1, characterized in that: the WiFi module (2) and the Bluetooth module (3) are electrically connected in parallel in a bidirectional mode through wires and the ARM processor (4).

4. The energy-saving environment-friendly intelligent system for paint coating curing according to claim 1, characterized in that: the ARM processor (4) is respectively electrically connected with the human-computer interaction (5), the external control signal (7) and the photoelectric isolation high-speed CAN bus interface (8) in a bidirectional parallel mode through wires.

5. The energy-saving environment-friendly intelligent system for paint coating curing according to claim 1, characterized in that: the output end of the photoelectric isolation high-speed CAN bus interface (8) is connected with a CAN controller, the output end of the CAN controller is connected with a site N processor, the input end of the site N processor is respectively connected with a voltage current acquisition circuit, an LED temperature acquisition control current circuit and a constant current driving circuit, and the output end of the constant current driving circuit is connected with an LEDN module.

6. The energy-saving environment-friendly intelligent system for paint coating curing according to claim 5, characterized in that: the photoelectric isolation high-speed CAN bus interface (8) is connected with the CAN controller in a bidirectional parallel electric connection mode through a wire, the CAN controller is connected with the site N processor in a bidirectional parallel electric connection mode through a wire, the site N processor is connected with the voltage current acquisition module and the LED temperature acquisition control current acquisition module respectively in a unidirectional series electric connection mode through wires, the site N processor is connected with the constant current driving circuit in a bidirectional parallel electric connection mode through a wire, and the constant current driving circuit is connected with the LEDN module in a unidirectional series electric connection mode through a wire.

7. The energy-saving environment-friendly intelligent system for paint coating curing according to claim 6, characterized in that: and N in the site N processor and the LEDN module is a natural number.

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