WO2020259221A1 - Curing lamp and curing control method therefor - Google Patents

Abstract

The present invention provides a curing lamp and a curing control method therefor. The curing lamp comprises at least one light source, a control system, a distance measuring device and a lamp housing. The light source is provided on the lamp housing, and the distance measuring device is provided on the lamp housing, so that the distance measuring device measures an irradiation distance from the light source to a coating layer; a power supply is electrically connected to the control system; the distance measuring device is communicatively coupled to the control system; and the control system is configured to control a working state of the light source on the basis of the irradiation distance detected by the distance measuring device.

Description

Curing lamp and curing control method thereof Technical field

The present invention relates to a light curing equipment, in particular to a curing lamp and a curing control method thereof.

Background technique

The coating drying methods mainly include natural drying, baking drying, and ultraviolet (infrared) light curing drying methods. Natural drying method The drying speed of the paint is slow, and it is easy to be polluted by the dust in the environment during the drying process. At the same time, it is also affected by the environmental humidity and wind speed, which affects the finish of the paint molding. The baking drying method has a slow drying speed and is suitable for drying water-based paints, but the baking drying method will cause greater environmental pollution and seriously affect the health of the operators. In addition, improper operation can damage the sprayed objects, such as furniture, walls, or the outer surface of cars. The UV (infrared) light curing and drying method has a fast drying speed, and the coating has a good curing effect after drying, and will not pollute the environment during the drying process, and will not affect the health of the operators.

The prior art paint drying, such as the drying of automobile paint, is to use large baking or light curing equipment in the paint booth to bake or irradiate the dried object for a long time to achieve the drying and curing of the paint on the surface of the automobile. The prior art paint drying equipment usually needs to be arranged in a paint booth, or directly irradiate the outer surface of the paint through a light curing lamp tube to dry the paint on the surface of the dried object. The prior art paint drying equipment, whether it is a baking type paint drying equipment or a light curing type paint drying equipment, has at least one of the following defects: First, the paint drying equipment is fixed and difficult to move or operate. That is to say, usually, the paint drying equipment is fixedly installed, and the distance between the paint surface and the light source of the paint drying equipment can only be adjusted by moving the paint attachment, such as the position of the vehicle. Although the mobile paint drying equipment can adjust the position according to the position of the paint surface. However, the mobile paint drying equipment of the prior art has high requirements on the operation technology of the operator, and the operator is required to maintain the distance between the paint drying equipment and the paint surface according to the type of paint and the thickness of the paint surface, so as to dry and cure the paint normally. . Secondly, the light intensity and light distance of the paint drying equipment are usually set according to the experience of the operator or artificially, but the prior art paint drying equipment cannot accurately measure the distance between the paint surface and the light fixture, and according to the paint surface and the light The distance between the lamps adjusts the light intensity of the paint drying equipment in real time. In addition, different types of coatings and different coating thicknesses require different drying and curing times. Generally, the later the coating thickness, the longer the coating drying equipment irradiates. However, the prior art paint drying equipment controls the irradiation time artificially, and requires professional technicians to detect the dryness of the paint surface. This may result in insufficient drying of the paint surface or excessive drying of the paint surface due to the irradiation time.

Summary of the invention

A major advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp can detect the distance between the curing lamp and the surface of a coating, so that the operator can adjust the position of the curing lamp based on the detection distance information .

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the light intensity of the curing lamp can be adjusted to adapt to different types of coatings, different irradiation distances, and different coating thicknesses.

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp can automatically adjust the light intensity of the curing lamp based on the detected distance between the curing lamp and the coating surface, To adapt to the irradiation distance of the curing lamp.

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp can detect and prompt the operator in real time the distance between the curing lamp and the cured coating, so that the operator can according to the cured coating Adjust the position of the curing lamp.

Another advantage of the present invention is to provide a curing lamp and a curing control method thereof, wherein the working status information of the curing lamp is prompted to the operator in a display mode, so that the operator can visually operate the curing lamp.

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp prompts the operator in real time according to the detected distance between the curing lamp and the cured coating and the illumination intensity of the curing lamp , So that the operator can grasp the curing time of the cured coating, thereby improving the curing efficiency and drying stability of the cured coating.

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the light intensity of the curing lamp changes with the irradiation distance, so that when the curing lamp is moved, the surface of the paint can be kept The amount of light received remains unchanged.

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp adjusts the distance between the curing lamp and the surface of the cured coating based on the size of the coating surface, and when the curing lamp When the distance from the surface of the cured paint changes, the light intensity of the curing lamp is automatically adjusted, so that the curing lamp is suitable for curing paint surfaces of different areas.

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp sets the irradiation distance of the curing lamp based on the material properties of the coating, so that the light intensity of the curing lamp is adapted to The cured material.

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp sets the irradiation time of the curing lamp based on the material properties of the coating to provide a suitable curing irradiation time for the coating .

Another advantage of the present invention is to provide a curing lamp and curing control method thereof, wherein the curing lamp sets the irradiation distance or irradiation time of the curing lamp based on the coating thickness, so that the light intensity of the curing lamp is adapted to Provide a suitable curing irradiation time for the cured material and the coating.

Another advantage of the present invention is to provide a curing lamp and its curing control method, wherein the curing lamp can automatically collect the material type of the coating, and based on the type of the coating to obtain the illumination time, irradiation distance, And light intensity, thus simplifying the operation process of coating curing. Therefore, the curing lamp provided by the present invention can reduce the operating difficulty of the operator, and can be operated without special expertise.

Another advantage of the present invention is to provide a curing lamp and its curing control method, wherein the curing lamp can emit a small area of irradiation beam, suitable for curing and drying small area coatings, such as automobiles (or other types of vehicles) ) Small area paint.

Another advantage of the present invention is to provide a curing lamp and a curing control method thereof, wherein the curing lamp can be operated in a handheld manner, which is convenient to use and adjust the position of the curing lamp relative to the coating surface.

Another advantage of the present invention is to provide a curing lamp and its curing control method, wherein the curing lamp can recommend the irradiation distance and light intensity of the curing lamp to the operator according to the type of coating and the set curing time, and When the irradiation distance of the curing lamp changes, the light intensity of the curing lamp is automatically adjusted so that the coating is cured within a set time.

Another advantage of the present invention is to provide a curing lamp and its curing control method, wherein the curing lamp recommends the illumination time and light intensity of the curing lamp to the operator according to the type of coating and the set irradiation distance, and when When the irradiation distance of the curing lamp changes, the light intensity of the curing lamp is automatically adjusted, so that the coating is cured within a set time.

Another advantage of the present invention is to provide a curing lamp and its curing control method, wherein the curing lamp recommends the illumination time and distance of the curing lamp according to the type of coating and the set light intensity, and when When the irradiation distance of the curing lamp changes, the illumination time of the curing lamp is automatically adjusted so that the coating can be cured by the curing lamp.

Other advantages and features of the present invention are fully embodied by the following detailed description and can be realized by the combination of means and devices specifically pointed out in the appended claims.

According to one aspect of the present invention, a curing lamp of the present invention, which can achieve the foregoing objectives and other objectives and advantages, is suitable for curing a coating by irradiation, including:

At least one light source;

A lamp housing; wherein the light source is provided in the lamp housing; and

A distance detection device, the distance detection device is arranged on the lamp housing, and the distance detection device detects the irradiation distance of the light source irradiated to the coating.

According to an embodiment of the present invention, further comprising a control system, wherein the power source is electrically connected to the control system, the distance detection device is communicatively connected to the control system, and the control system is configured to be based on The irradiation distance detected by the distance detecting device controls the working state of the light source.

According to an embodiment of the present invention, wherein the light source and the distance detecting device are fixedly installed in the lamp housing, and the distance detecting device is arranged adjacently in the same direction as the irradiation direction of the light source In the light source, the distance detection device detects the distance between the light source and the coating.

According to an embodiment of the present invention, the distance detection device is selected from any detector group consisting of an ultrasonic distance detection device, an infrared distance detection device, and a laser distance detection device.

According to an embodiment of the present invention, the distance detecting device includes an ultrasonic generating device, an ultrasonic receiving device, and an ultrasonic processing device, and the ultrasonic processing device is communicably connected to the ultrasonic generating device and the ultrasonic processing device. An ultrasonic receiving device, wherein the ultrasonic processing device is configured to obtain the light source and the light source based on an ultrasonic detection signal emitted by the ultrasonic generating device and a detection echo of the ultrasonic detection signal received by the ultrasonic receiving device The irradiation distance between the coatings.

According to an embodiment of the present invention, the control system includes a circuit board and a processor, wherein the light source is electrically connected to the processor through the circuit board, and the distance detection device is communicatively connected to the processor. The distance detection device transmits detection distance information to the processor, and the processor controls the light intensity of the light source.

According to an embodiment of the present invention, the control system further includes a control switch that is electrically connected to the circuit board, and the control switch controls the on and off of the light source through the circuit board.

According to an embodiment of the present invention, the light source includes at least one curing light unit and a light source controller, wherein the curing light unit is electrically connected to the circuit board of the control system by the light source controller, and The light source controller controls the light intensity of the curing light unit based on the electrical signal transmitted by the circuit board.

According to an embodiment of the present invention, the curing lamp further includes a curing setting unit, wherein the curing setting unit sets a curing data parameter to the processor, wherein the processor is based on the setting of the curing setting unit The curing data parameter controls the working state of the light source.

According to an embodiment of the present invention, the curing setting unit inputs the coating data information to the processor, wherein the processor controls the illumination time and light intensity of the light source based on the coating data information.

According to an embodiment of the present invention, the curing lamp further includes a prompt unit, wherein the prompt unit is communicatively connected to the distance detection device, wherein the distance detection device transmits the detected distance information to the prompt unit , The irradiation distance information of the curing lamp is prompted by the prompt unit.

According to an embodiment of the present invention, the prompting unit is communicatively connected to the control system, wherein the processor of the control system transmits the working status information of the curing lamp to the prompting unit, by the The prompt unit prompts the working state of the curing lamp.

According to an embodiment of the present invention, the curing setting unit sets a curing time and inputs coating data information to the processor, and the processor is based on the data information set by the curing setting unit and the distance detection device The collected illumination distance information controls the light intensity of the light source.

According to an embodiment of the present invention, the curing setting unit sets the light intensity and inputs coating data information to the processor, and the processor is based on the data information set by the curing setting unit and the distance detection device The collected illumination distance information controls the illumination time of the light source.

According to an embodiment of the present invention, the curing setting unit sets the curing irradiation area of the curing lamp and inputs the coating data information to the processor, and the processor obtains the result based on the curing irradiation area. The irradiation distance information of the curing lamp is described, and the light intensity and the light time of the light source are controlled according to the change of the irradiation distance.

According to an embodiment of the present invention, the curing lamp further includes at least one paint collection device that collects paint information of the cured coating, and the paint collection device is communicatively connected to all the curing lamps. The curing setting unit, wherein the paint collecting device transmits the collected paint information to the curing setting unit.

According to an embodiment of the present invention, the curing lamp further includes a heat dissipation device, wherein the light source is disposed adjacent to the heat dissipation device, and the temperature of the light source is reduced by the heat dissipation device.

According to an embodiment of the present invention, the heat dissipation device includes a heat conduction device, wherein the light source is connected to the heat conduction device in a thermally conductive manner, and the heat generated by the light source is conducted to the heat conduction device.

According to an embodiment of the present invention, the heat conduction device has a heat conduction cavity and at least one set of heat dissipation channels communicating with the outside world and the heat conduction cavity, wherein the light source is arranged in the heat conduction cavity by the lamp housing, and the heat dissipation The heat in the channel is conducted to the external environment through the heat dissipation channel.

According to an embodiment of the present invention, the heat conduction device further includes an air cooling device, wherein the air cooling device is disposed in the heat conduction cavity of the heat conduction device, and the air cooling device is electrically connected to the circuit board , The air cooling device blows air in the heat conduction cavity to accelerate the air convection between the heat conduction cavity and the external environment.

According to an embodiment of the present invention, the lamp housing includes a lamp cover and a lamp head, wherein the lamp cover fixes the light source and the distance detection device to the heat dissipation device, wherein the heat dissipation device is provided In front of the lamp head, the lamp head maintains the light irradiation direction of the light source by supporting the heat dissipation device.

According to an embodiment of the present invention, the lamp head further has a visible window formed on the rear side of the lamp head, wherein the prompt unit is provided on the lamp head The visible window.

According to an embodiment of the present invention, the lamp housing further includes a handle portion and a lamp holder portion, wherein the handle portion extends downward from the rear side of the lamp head, and the lamp holder portion is located at the handle portion , Wherein the lamp holder part supports the lamp head through the handle part, and the handle part is adapted to be gripped and operated.

According to an embodiment of the present invention, the curing lamp further includes a power supply system, wherein the power supply system is electrically connected to the circuit board of the control system, so that the circuit board provides the power supply and the distance The detection device is powered.

According to an embodiment of the present invention, the power supply system includes a battery and at least one power external device, wherein the power external device is electrically connected to the battery, and the power external device can charge the battery.

According to an embodiment of the present invention, the power supply external device further includes a direct charging unit, wherein the direct charging unit is electrically connected to the circuit board, and the direct charging unit provides electrical energy to the light source through the circuit board And the distance detection device.

According to an embodiment of the present invention, the direct charging unit is arranged on the lower side of the lamp housing, and the charging opening of the direct charging unit faces the rear of the curing lamp.

According to an embodiment of the present invention, the external power supply device further includes a charging unit, wherein the base charging unit is electrically connected to the battery, and the base charging unit can store electrical energy to the battery.

According to an embodiment of the present invention, the socket charging unit is disposed under the lamp socket part of the lamp housing.

According to an embodiment of the present invention, the curing lamp further includes at least one base, wherein the lamp housing of the curing lamp can be stored in the base, and the curing lamp is received and supported by the base. light.

According to an embodiment of the present invention, the base includes a base body and further has at least one storage cavity, wherein the lamp holder portion of the curing lamp can be received into the storage cavity by the base body.

According to an embodiment of the present invention, the base further includes a locking device, the locking device is movably disposed on the base body, and the lamp holder portion of the curing lamp has at least one slot When the lamp holder part of the curing lamp is received in the storage cavity, the locking device is engaged with the groove of the lamp holder part to restrict the movement of the lamp holder part.

According to an embodiment of the present invention, the base further includes at least one connecting member, wherein the connecting member is disposed below the base body, and the connecting member connects the base to a support.

According to an embodiment of the present invention, the base further includes at least one charging unit, the charging unit is arranged below the charging body, when the lamp holder part of the curing lamp is received in the receiving cavity When the charging unit is electrically connected to the dock charging unit, the dock charging unit charges the battery.

According to another aspect of the present invention, the present invention further provides a curing control method of a curing lamp, wherein the curing control method includes the following steps:

(a) Light irradiates a coating and detects the irradiation distance between a light source and the coating; and

(b) Obtain curing data information of the coating being cured based on the detected irradiation distance, and adjust the working state of a light source of the curing lamp according to the curing data information.

According to an embodiment of the present invention, before the step (b) of the curing control method, the method further includes: inputting paint information of the coating to be cured, wherein the paint information includes the type of paint of the coating And the coating thickness of the coating.

According to an embodiment of the present invention, in the step (b) of the curing control method, a light intensity of the curing light is set, and the light time of the curing light is controlled according to the irradiation distance of the curing light .

According to an embodiment of the present invention, in the step (b) of the curing control method, an illumination time of the curing lamp is set, and the light source of the curing lamp is controlled according to the irradiation distance of the curing lamp The light intensity.

According to an embodiment of the present invention, in the step (b) of the curing control method, the irradiation distance of the curing lamp to the coating is set based on the cured area of the coating, and according to the The irradiation distance of the curing lamp controls the light intensity and irradiation time of the light source of the curing lamp.

According to an embodiment of the present invention, after the step (a) of the curing control method, the method further includes the step: based on the detected distance, displaying the irradiation distance information of the curing lamp to remind the operator to operate the Curing lamp.

According to one embodiment of the present invention, after the step (b) of the curing control method, the step (c) displays the working status of the work lamp in real time based on the obtained curing data information of the coating.

Through the understanding of the following description and the drawings, the further objectives and advantages of the present invention will be fully embodied.

These and other objectives, features and advantages of the present invention are fully embodied by the following detailed description, drawings and claims.

Description of the drawings

Fig. 1 is an overall schematic diagram of a curing lamp according to the first preferred embodiment of the present invention.

Fig. 2 is an exploded schematic diagram of the curing lamp according to the above-mentioned preferred embodiment of the present invention.

3 is a perspective cross-sectional view of the curing lamp according to the above preferred embodiment of the present invention.

Fig. 4A is a side view of the curing lamp according to the above-mentioned preferred embodiment of the present invention.

Fig. 4B is a bottom view of the curing lamp according to the above preferred embodiment of the present invention.

Fig. 5A is a schematic diagram of an alternative embodiment of the upper structure of the curing lamp according to the above preferred embodiment of the present invention.

Fig. 5B is a schematic diagram of another alternative embodiment of a light source of the curing lamp according to the above-mentioned preferred embodiment of the present invention.

Fig. 5C is a schematic diagram of another alternative embodiment of a distance measuring device for the curing lamp according to the above preferred embodiment of the present invention.

5D is a schematic diagram of another alternative implementation of the distance measuring device of the curing lamp according to the above preferred embodiment of the present invention.

Fig. 6 is a schematic diagram of a base of the curing lamp according to the above preferred embodiment of the present invention.

Fig. 7A is a schematic diagram of a usage scene of the curing lamp according to the above-mentioned preferred embodiment of the present invention.

Fig. 7B is a schematic diagram of another usage scenario of the curing lamp according to the above preferred embodiment of the present invention.

Fig. 8 is a schematic diagram of the detection distance of the curing lamp according to the above preferred embodiment of the present invention.

Fig. 9 is a schematic diagram of a paint collecting device of the curing lamp collecting coating materials according to the above preferred embodiment of the present invention.

Fig. 10 is a schematic diagram of another use scene of the curing lamp according to the above-mentioned preferred embodiment of the present invention, wherein the figure shows that the light intensity of the curing lamp changes with the irradiation distance.

Detailed ways

The following description is used to disclose the present invention so that those skilled in the art can implement the present invention. The preferred embodiments in the following description are merely examples, and those skilled in the art can think of other obvious modifications. The basic principles of the present invention defined in the following description can be applied to other embodiments, modifications, improvements, equivalents, and other technical solutions that do not depart from the spirit and scope of the present invention.

Those skilled in the art should understand that, in the disclosure of the present invention, the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", " The orientation or positional relationship indicated by "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are based on the orientation or positional relationship shown in the drawings, which is only for the convenience of describing the present invention And to simplify the description, rather than indicating or implying that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, so the above terms should not be understood as limiting the present invention.

It can be understood that the term "a" should be understood as "at least one" or "one or more", that is, in one embodiment, the number of an element may be one, while in other embodiments, The number can be multiple, and the term "one" cannot be understood as a restriction on the number.

1 to 7B of the accompanying drawings of the specification of the present invention, a curing lamp according to the first preferred embodiment of the present invention is illustrated in the following description. The curing lamp emits an irradiation light to irradiate a coating layer 100, and the curing lamp cures the coating layer 100 in a light irradiation manner. It is understandable that the curing lamp emits light capable of curing the coating 100 based on the material type of the coating 100, such as infrared light, ultraviolet light, or other specific wavelength light. The coating 100 is coated or sprayed on the surface of an attached object, such as the outer surface of a vehicle, the surface of furniture such as tables and chairs, or the surface of a wall. Therefore, the coating 100 may be a car paint sprayed on a vehicle, a paint on a furniture surface, or a paint lamp coating on a wall. It is worth mentioning that, in the preferred embodiment of the present invention, the type of the coating 100 and the type of the adherend are merely exemplary here, and not limited. In other words, the curing lamp can be applied to the drying and curing of car paint, the drying and curing of furniture paint, the drying and curing of wall paint, and the like. It can be understood that the type of light emitted from the curing lamp is only an example here, and not a limitation.

As shown in FIG. 2, the curing lamp includes at least one light source 10, a control system 20, a lamp housing 30, and a distance detection device 40, wherein the light source 10 and the control system are arranged in the lamp housing 30. The light source 10 is electrically connected to the control system 20, and the operating state of the light source 10 is controlled by the control system 20. When the light source 10 is energized, it emits light capable of drying or curing the coating 100, such as ultraviolet light or infrared light. The distance detection device 40 detects the distance between the curing lamp and the irradiated coating 100, wherein the control system 20 is communicatively connected to the distance detection device 40, and the control system 20 is based on the distance detection The distance between the curing lamp and the irradiated coating 100 detected by the device 40 prompts the operator so that the operator can maintain a proper light irradiation distance. In this preferred embodiment of the present invention, the distance detecting device 40 is disposed on the lamp housing 30, and the distance detecting device 40 is held by the lamp housing 30.

Preferably, in this preferred embodiment of the present invention, the distance detecting device 40 is disposed adjacent to the light source 10, and the distance detecting device 40 detects the distance between the light source 10 and the coating 100 . The distance detection device 40 transmits the detection distance information of the light source 10 and the coating 100 to the control system 20, wherein the control system 20 controls the light intensity and/or light intensity of the light source 10 based on the detection distance information Or lighting time, so that the light source 10 provides the coating 100 with a suitable light intensity and a suitable lighting time at the current irradiation distance.

In this preferred embodiment of the present invention, the distance detection device 40 detects the distance between the light source 10 and the coating 100 in a wireless detection manner. Preferably, the distance detection device 40 may be, but is not limited to, an ultrasonic detection device, wherein the distance detection device 40 emits an ultrasonic wave toward the coating 100 and receives the ultrasonic echo reflected by the coating 100, The distance detecting device 40 obtains the distance between the distance detecting device 40 and the coating 100 according to the received ultrasonic wave and the received ultrasonic wave back. It can be understood that, in this preferred embodiment of the present invention, the distance detecting device 40 is disposed adjacent to the light source 10. Therefore, the distance between the distance detection device 40 and the coating 100 detected by the distance detection device 40 can be regarded as the distance between the light source 10 and the coating 100, or can be regarded as the distance between the light source 10 and the coating 100. 20 obtain the distance between the light source 10 and the coating 100 based on the distance information detected by the distance detection device 40.

The distance detection device 40 includes at least one ultrasonic generating device 41, at least one ultrasonic receiving device 42, and an ultrasonic processing device 43, wherein the ultrasonic generating device 41 and the ultrasonic receiving device 42 are electrically connected to the ultrasonic processing device.装置43. The ultrasonic generating device 41 generates and sends out an ultrasonic detection signal. When the ultrasonic detection signal detects an object to be detected, such as the coating 100, the coating 100 reflects the ultrasonic The echo to the ultrasonic receiving device 42. The ultrasonic receiving device 42 receives the echo of the ultrasonic, and the ultrasonic processing device 43 obtains the coating 100 and the echo based on the transmitted ultrasonic detection signal and the received echo of the ultrasonic The distance of the distance detection device 40. The ultrasonic processing device 43 of the distance detecting device 40 is communicably connected to the control system 20, wherein the irradiation distance information detected by the ultrasonic processing device 43 is transmitted to the control system 20, and The control system 20 controls the light intensity, light time, etc. of the light source 10 based on the irradiation distance information.

It can be understood that, in this preferred embodiment of the present invention, the specific implementation of the distance detection device 40 is merely exemplary in nature and not limiting. Therefore, in other optional embodiments of the present invention, the distance detection device 40 can also be implemented as other types of distance detectors, such as laser distance detectors, infrared distance detectors, and the like.

As shown in Figures 1 to 3, the light source 10 and the distance detecting device 40 are arranged in the lamp housing 30, wherein the lamp housing 30 holds the distance detecting device 40 and the light source 10 so as to make The distance detecting device 40 is arranged adjacent to the light source 10. The light source 10 includes at least one curing light unit 11 and at least one light source controller 12, wherein the light source controller 12 is communicatively connected to the curing light unit 11 and the control system 20. The light source controller 12 controls the working state of the curing light unit 11 based on the control instructions of the control system 20, such as the switch, light intensity, and lighting time of the curing light unit 11. The curing light unit 11 is controlled by the light source controller 12 to generate and emit irradiation light, such as ultraviolet light and infrared light, for curing the coating layer 100 in a energized state. Preferably, in this preferred embodiment of the present invention, the curing light unit 11 may be, but not limited to, an LED light emitting device.

As shown in FIGS. 2 and 3, the control system 20 generates at least one control command corresponding to the light source 10 based on the distance information between the curing lamp and the coating 100 detected by the distance detecting device 40 , To control the working state of the light source 10. The control system 20 includes a control switch 21, a processor 22, and a circuit board 23, wherein the control switch 21 and the processor 22 are electrically connected to the circuit board 23, and the circuit board 23 transmits The control signals of the control switch 21 and the processor 22 are sent to the light source controller 12 of the light source 10 to control the working state of the light source 10. The ultrasonic processing device 43 of the distance detection device 40 is communicatively connected to the processor 22 of the control system 20, wherein the processor 22 generates a control command based on the detection distance information and transmits the The control command is sent to the circuit board 23, and the control signal is transmitted to the light source 10 through the circuit board 23. The control switch 21 controls the on and off of the power source of the light source 10 of the curing lamp, thereby controlling the working state of the curing lamp. The control switch 21 of the control system 20 is arranged on the lamp housing 30, wherein the control switch 21 is operated to send a control instruction to the circuit board 23 to control the working state of the light source 10.

It is understandable that the circuit board 23 of the control system 20 obtains a control electrical signal corresponding to the light source 10 based on the control instruction sent by the processor 22, and transmits the control electrical signal to the light source The light source controller 12 of 10 is used for the light source controller 12 to execute the control electrical signal and control the working state of the curing light unit 11. Preferably, the processor 22 may be, but not limited to, MCU (Microcontroller Unit, micro control unit), DSP, FPGA, and an integrated chip composed of them.

The light source controller 12 of the light source 10 receives the control electrical signal sent by the circuit board 23 of the control system 20, and controls the working state of the curing light unit 11 based on the signal, such as controlling the curing The light unit 11 is turned on or off, the light intensity of the curing light unit 11 is controlled, and the lighting time of the curing light unit 11 is controlled.

As shown in FIGS. 2 to 4B, the curing lamp further includes a curing setting unit 50, wherein the curing setting unit 50 is communicatively connected to the control system 20, and the operator can input the pairing through the curing setting unit 50 A curing control information of the coating 100, such as setting the light intensity of the light source 10, setting the light time of the light source 10, setting the irradiation distance between the curing lamp and the coating 100, setting the The coating information of the coating 100, such as the type of coating of the coating 100, and the thickness of the coating. The processor 22 of the control system 20 controls the working state of the light source 10 based on the curing control information input by the curing setting unit 50.

It is understandable that the processor 22 of the control system 20 is based on the coating information of the coating 100 input by the curing setting unit 50, such as the type of coating, the area of the coating, and the thickness of the coating. Layer information to generate at least one curing control scheme for curing the coating 100, wherein the curing control scheme includes the irradiation distance between the curing lamp and the coating 100, and the light intensity of the light source 10 of the curing lamp , Lighting time and other information. On the other hand, when the working state of the curing lamp changes, for example, the light intensity of the light source 10 of the curing lamp, the irradiation distance between the curing lamp and the coating 100, or the light time, etc. When any factor changes, the control system 20 adjusts the working state of the light source 10 based on the curing control information input by the curing setting unit 50 to improve the curing effect of the coating 100.

When the curing lamp is working, the distance detecting device 40 of the curing lamp collects the irradiation distance H between the light source 10 of the curing lamp and the coating 100, wherein the controller system 20 The processor 22 automatically controls the lighting time of the light source 10 based on the irradiation distance, the coating information of the coating 100 and the set light intensity. That is to say, when the irradiation distance H changes, the processor 22 controls the light source 10 in a manner of adjusting the illumination time while keeping the light intensity of the light source 10 unchanged, so that the curing The lamp cures the coating 100 within a prescribed time, thereby improving the curing efficiency of the curing lamp. The processor 22 automatically controls the light intensity of the light source 10 based on the irradiation distance, the coating information of the coating 100 and the set light time. That is to say, when the irradiation distance H changes, the processor 22 controls the light source 10 in a manner of adjusting the light intensity while keeping the illumination time of the light source 10 unchanged, so that the curing The lamp cures the coating 100 within a prescribed time, thereby improving the curing efficiency of the curing lamp.

When the irradiation distance between the curing lamp and the coating 100 changes, the processor 22 of the control system automatically controls the light intensity or the light time of the light source 10 based on the set curing lighting parameters , So that the coating 100 achieves a suitable drying and curing effect.

Preferably, in this preferred embodiment of the present invention, when the irradiation distance between the curing lamp and the coating 100 changes, the control system 20 controls the light intensity of the light source 10 so that the unit area The amount of light received by the light source 10 on the surface of the coating 100 remains unchanged, so that the coating 100 is cured within the set illumination time.

It is understandable that when the irradiation distance between the curing lamp and the coating 100 remains unchanged, the greater the light intensity of the curing lamp, the greater the amount of light received on the surface of the coating 100, The coating 100 is cured for a shorter time. Therefore, the curing lamp can control the curing time of the coating 100 by adjusting the light intensity of the light source 10, or adjust the light intensity of the light source 10 according to the set curing time, so as to cure within a set time. The coating 100. On the other hand, when the light intensity of the light source 10 of the curing lamp remains unchanged, the greater the irradiation distance between the curing lamp and the coating 100, the larger the area irradiated by the curing lamp The less the amount of curing light received by the coating 100 per unit area, the longer the curing time of the coating 100. Therefore, the curing area of the coating 100 by the curing lamp can be adjusted by adjusting the distance H between the curing lamp and the coating 100.

In this preferred embodiment of the present invention, the curing setting unit 50 inputs the curing control information to the control system 20 in a voice input mode; or inputs the curing control information to the control system in a key setting mode. System 20; or obtain the curing control information transmitted by external electronic equipment to the control system 20 in a network connection. It can be understood that, in the preferred embodiment of the present invention, the specific implementation of the curing setting unit 50 is merely exemplary, and not limiting. Therefore, in other optional embodiments of the present invention, the curing setting unit 50 may also be implemented as another information input device, such as a touch screen input device.

It is understandable that the curing setting unit 50 can be implemented as a voice input device, wherein the voice input device receives a voice message and converts the voice message to the control system 20. Optionally, the curing setting unit 50 may be implemented as a key input device, in which an operator inputs the curing control information to the control system 20 by operating keys. Optionally, the curing setting unit 50 can be implemented as a network communication interface, wherein the network communication interface is communicatively connected to the control system 20, and external electronic devices, such as computers, mobile phones, remote controls, etc., pass through The network communication interface is communicatively connected to the control system 20. The external electronic device is communicatively connected to the curing lamp through the curing setting unit 50 and transmits the curing control information to the control system 20.

The processor 22 of the control system 20 generates at least one piece of control information for controlling the light source 10 based on the curing control information input by the curing setting unit 50 and the distance information detected by the distance detecting device 40, thereby The working state of the light source 10 is controlled. In detail, when the curing setting unit 50 sets the light source 10 to work at a fixed illumination intensity, the control system is based on the paint information set by the curing setting unit 50 and the distance detection device 40 detects the The distance information automatically generates the lighting time of the light source 10. When the curing setting unit 50 sets the light source 10 to irradiate and cure the coating 100 for a fixed lighting time, the control system 20 is based on the paint information set by the curing setting unit 50 and the distance detection device 40 The detected distance information automatically controls the illumination intensity of the light source 10.

2 to 4B, the curing lamp further includes at least one prompt unit 60, wherein the prompt unit 60 is communicatively connected to the control system 20, the control system 20 generates at least one corresponding to the coating 100 A prompt message is sent to the prompt unit 60, and the operator is prompted by the prompt unit 60. The prompt unit 60 prompts the operator based on the working state information of the curing lamp provided by the control system 20, so that the operator can operate the curing lamp or adjust the position of the curing lamp according to the prompt information provided by the prompt unit 60 Or adjust the working state of the curing lamp.

It is understandable that the working status information of the curing lamp, such as the irradiation distance of the curing lamp, the intensity of the illumination, etc., is prompted to the current operator through the prompt unit 60, so that the operator can adjust based on the prompt information The working state of the curing lamp, such as the irradiation distance of the curing lamp, the lighting intensity of the curing lamp, etc., in order to control the working state of the curing lamp in a timely manner according to the curing degree of the cured coating, so as to have It is beneficial to improve the drying quality of the cured coating, reduce the energy consumption of the curing lamp, and improve the working efficiency of the curing lamp.

The prompt unit 60 prompts the operator based on the working status information of the curing lamp provided by the control system 20 in the form of text, numbers, graphics or patterns; or the prompt unit 60 is based on the information provided by the control system 20 The operating status information of the curing lamp is prompted by voice prompts to the operator; or the prompt unit 60 is transmitted to the operator in a communication connection based on the operating status information of the curing lamp provided by the control system 20 An electronic device, such as an operator’s mobile phone, computer, or remote control and other electronic communication devices.

Correspondingly, the prompt unit 60 can be implemented as a display device, wherein the display device displays the operating state information of the curing lamp, such as the distance information between the coating 100 and the curing lamp, The light intensity of the light source 10, the lighting time of the light source 10, the information of the coating 100, and the like. Optionally, the prompt unit 60 can be implemented as a voice prompt device, wherein the voice prompt device prompts the operator with voice prompts about the working status of the curing lamp, such as the coating 100 and the The distance information between the curing lamps, the light intensity of the light source 10, the lighting time of the light source 10, the information of the coating 100, and the like. Optionally, the prompt unit 60 may be implemented as a communication connection device, wherein the communication connection device is communicatively connected to the electronic equipment of the operator, such as a mobile phone, a computer, an electronic monitoring platform, etc., the prompt unit 60 transmits the working status information of the curing lamp to the electronic device, and the electronic device prompts the operator.

Figure 5A of the drawings of the specification of the present invention shows an alternative embodiment of the curing lamp, wherein the curing lamp is implemented as a hand-held lamp, and the light source 10 and the distance detection of the curing lamp The device 40 is fixed to the lamp housing 30, and the distance detecting device 40 is kept adjacent to the light source 10 by the lamp housing 30, so that the distance detecting device 40 detects that the light source 10 is irradiated to the coating 100 distance.

Figure 5B of the accompanying drawings of the specification of the present invention shows another alternative implementation of the curing lamp. In this preferred embodiment of the present invention, the curing lamp differs from the above preferred embodiment in that the light source 10 and the distance detection device 40. The light source 10 includes a plurality of curing light units 11, wherein the curing light unit 11 and the distance detecting device 40 are fixedly arranged on the lamp housing 30. Exemplarily, when the number of the curing light units 11 of the light source 10 is three, the curing light units 11 are arranged at intervals in front of the lamp housing 30, and the distance detecting device 40 is It is arranged between the curing light units 11, and the distance between each curing light unit 11 and the coating 100 is detected by the distance detecting device 40. It is understandable that in this preferred embodiment of the present invention, the irradiation and working efficiency of the curing lamp can be increased by increasing the number of the curing light units 11, thereby reducing the irradiation time of the coating 100. In addition, the curing light units 11 are arranged at intervals, which can increase the irradiation area of the curing lamp. It is worth mentioning that, in this preferred embodiment of the present invention, the distance detecting device 40 may be, but not limited to, an infrared distance detecting device or a laser detecting device.

Figure 5C of the accompanying drawings of the specification of the present invention shows another alternative embodiment of the curing lamp. In this preferred embodiment of the present invention, the difference between the curing lamp and the above preferred embodiment lies in the distance测装置40。 Detection device 40. The distance detection device 40 is implemented as a laser detector, wherein the distance detection device 40 outwardly emits a laser detection beam and a reflected beam that receives the detection laser, and is based on the emitted detection beam and the received The reflected beam detection obtains the distance between the distance detection device 40 and the coating 100. Preferably, in this preferred embodiment of the present invention, the distance detecting device 40 is arranged adjacent to the light source 10, and the distance detecting device 40 detects the distance between the light source 10 and the coating 100 , That is, the irradiation distance of the light source 10.

Figure 5D of the accompanying drawings of the specification of the present invention shows another alternative embodiment of the curing lamp. In this preferred embodiment of the present invention, the difference between the curing lamp and the above preferred embodiment lies in the distance测装置40。 Detection device 40. In the preferred embodiment of the present invention, the distance detecting device 40 is disposed on the lamp housing 30, and the distance detecting device 40 is supported and fixed by the lamp housing 30. The distance detection device 40 is arranged adjacent to the light source 10 through the lamp housing 30, and the distance between the light source 10 and the coating 100 is detected by the distance detection device 40. Preferably, in this preferred embodiment of the present invention, the distance detecting device 40 is arranged above the lamp housing 30. It can be understood that the location where the distance detection device 40 is installed is merely an example here, and not a limitation.

As shown in FIGS. 2 to 4B, the curing lamp further includes a heat dissipation device 70, wherein the heat dissipation device 70 is disposed adjacent to the light source 10, and the heat dissipation device 70 reduces Heat, to prevent heat from accumulating near the light source 10, mirroring the normal illumination of the light source 10. Preferably, in this preferred embodiment of the present invention, the heat dissipation device 70 reduces the heat near the light source 10 by means of heat transfer or air cooling.

Those skilled in the art can understand that the temperature of the light source 10 and the distance detection device 40 should not be too high during normal operation, and when the temperature exceeds a limited temperature, the power of the light source 10 to emit curing light effects may be affected. When the curing lamp is irradiated, the heat generated by the light source 10 will affect the distance detection device 40, causing the temperature of the distance detection device to be too high. Similarly, an excessively high temperature will also affect the normal detection operation of the distance detection device 40, thereby causing the distance detection device to malfunction or affect the detection accuracy. Therefore, the heat dissipation device 70 reduces the temperature of the light source 10 and the distance detection device 40, thereby providing a suitable working temperature environment for the light source 10 and the distance detection device.

Correspondingly, the heat dissipating device 70 further includes a heat conducting device 71 and an air cooling device 72, wherein the heat conducting device 71 is connected to the curing light unit 11 of the light source 10 in a thermally conductive manner, wherein when the The heat generated by the light source 10 during operation is transferred to the heat conducting device 71, and the heat energy generated by the light source 10 is dissipated to the external environment by the heat conducting device 71. The lamp housing 30 fixes the curing light unit 11 of the light source 10 to the heat conducting device 71 so that the heat generated by the curing light unit 11 during the irradiation operation is conducted to the heat conducting device 71. The heat conduction device 71 further has a heat conduction cavity 711 and at least a set of heat dissipation channels 712, wherein the light source 10 is held in the heat conduction cavity 711 by the lamp housing 30. The heat dissipation channel 712 is a through hole formed in the heat conduction device 71, wherein the heat dissipation channel 712 communicates with the external environment and the heat conduction cavity 711, wherein the airflow in the heat conduction cavity 711 passes through the heat dissipation channel and the external environment Circulate each other, so that the heat dissipation device 70 reduces the heat in the heat conduction cavity 712 by means of convection. Preferably, in this preferred embodiment of the present invention, the heat dissipation channel 712 is formed at the lower end of the heat conduction device 71, and the heat dissipation channel 712 of the heat conduction device 71 guides the heat conduction cavity 711 The gas flows downward. It is understandable that the heat conducting device 71 is made of materials with good thermal conductivity, such as metals or metal alloy materials such as copper, aluminum, and iron, or non-metallic materials such as graphene. It can be understood that the material of the heat conducting device 71 is only exemplary here, and not a limitation.

It is worth mentioning that the heat dissipation device can also reduce the influence of the light source 10 on the distance detection device 40 by separating the light source 10 and the distance detection device 40.

The air-cooling device 72 is electrically connected to the circuit board 23 of the control system 20, wherein the control system 20 controls the operation of the air-cooling device 72. The air-cooling device 72 generates air convection between the heat conduction cavity 711 and the external environment in a blowing manner, so as to reduce the heat in the heat conduction cavity 711. In this preferred embodiment of the present invention, the air-cooling device 72 can be, but not limited to, a fan, wherein the air-cooling device is fixedly installed on the heat conducting device 71, and the heat conducting device 71 removes the wind The cooling device 72 is held adjacent to the light source 10. When the temperature in the light source 10 or the heat conducting cavity 711 is high, the control system 20 controls the air cooling device 72 to work to reduce the temperature of the light source 10.

Correspondingly, the heat dissipation device 70 further includes at least one temperature collection device 73, wherein the temperature collection device 73 collects the temperature in the heat conduction cavity 712 of the light source 10 or the heat dissipation device 70. The temperature collection device 73 is communicatively connected to the control system 20, and the temperature information collected by the temperature collection device 73 is transmitted to the processor 22 of the control system 20. When the light source 10 or the When the temperature of the heat conduction cavity 712 exceeds the set value T, the processor 22 controls the activation of the air cooling device 72 to accelerate the heat dissipation efficiency of the heat dissipation device 70 and thereby reduce the temperature of the light source 10.

The temperature collecting device 73 is kept in the heat conducting cavity 712 to collect the temperature of the heat conducting cavity 712. Preferably, the temperature collecting device 73 is arranged adjacent to the curing light unit 11 of the light source 10 so that the temperature data collected by the temperature collecting device 73 is close to the temperature of the light source 10.

As shown in FIGS. 2 to 4B, the curing lamp further includes a power supply system 80, wherein the power supply system 80 is electrically connected to the circuit board 23 of the control system 20, and the circuit board 23 is The power-consuming units of the curing lamp provide electrical energy, such as the light source 10, the distance detection device 40, the curing setting unit 50, the prompt unit 60, and the heat dissipation device 70. In this preferred embodiment of the present invention, the power supply system 80 can supply power to the power-consuming units of the curing lamp by means of battery power supply or by means of an external power supply.

Correspondingly, the power supply system 80 includes at least one battery 81, wherein the battery 81 is electrically connected to the circuit board 23, and the circuit board 23 supplies power to the electric units of the curing lamp. The battery 81 is fixedly arranged at the lower part of the lamp housing 30, and the center of gravity of the curing lamp is lowered by the battery 81, so as to stabilize the curing lamp during use. Preferably, the battery 81 is a rechargeable device, such as a lithium battery, a nickel-cadmium battery, a nickel-hydrogen battery, a lead storage battery, an iron-lithium battery, and the like. The power supply system 80 further includes at least one power supply external device 82, wherein the power supply external device 82 is electrically connected to the circuit board 23 to an external power supply through a cable, wherein the power supply external device 82 obtains and transforms the external power supply The electrical energy of the curing lamp can be used for the operation of the electrical units of the curing lamp. It can be understood that the external power supply device 82 is implemented as an external power supply interface of the curing lamp. The external power supply device 82 is electrically connected to the battery 81 through the circuit board 23, and the electrical energy of the external power supply is stored in the battery 81 through the external power supply device 82.

It is worth mentioning that when the battery 81 of the power supply system 80 is powered by the battery 81 alone, the curing lamp may not be restricted by its position. At this time, the curing lamp does not need to be powered by an external power source, but works independently. That is to say, when the battery 81 is powered by the battery 81 alone, the curing lamp can work in an environment with a power source without being restricted by a working place and a power source, such as curing of car paint in an outdoor environment. When the external power supply device 82 of the power supply system 80 is connected to an external power supply, the curing lamp can continuously work under the connection of the external power supply, and can charge the battery 81 during operation.

In the present invention, the curing lamp can be used as a small light curing device to light cure the coating 100 in a small area or a small area. Preferably, the curing lamp is implemented as a hand-held curing device, that is, the curing lamp can be operated in a hand-held manner, and the user can use any one or more methods such as holding, holding, and hand-held. The curing lamp irradiates the coating 100. In short, in this preferred embodiment of the present invention, the use of the curing lamp is not limited here.

As shown in Figures 2 to 4B, the lamp housing 30 includes a lamp cover 31, a lamp head 32, a handle 33, and a lamp holder 34, wherein the lamp cover 31 fixes the light source 10 in The heat dissipating device 70 and the distance detecting device 40 are kept adjacent to the light source 10. It can be understood that the lamp cover 31 fixes the light source 10 and the distance detection device 40 to the heat dissipation device 70. The heat dissipation device 70 is arranged at the front end of the lamp head 32, wherein the lamp head 32 supports and fixes the heat dissipation device 70, and the lamp head 32 supports the heat dissipation device 70 to maintain the The light irradiation direction of the light source 10.

The lamp head 32 integrally extends upward from the handle portion 33, and the handle portion 33 is suitable for being used by a user in a hand-held or grasped manner. The prompt unit 60 is arranged behind the lamp head 32, wherein the lamp head 32 further has a visible window 321, and the prompt unit 60 and the curing setting unit 50 are installed on the lamp head 32. The visual window 321, wherein the prompt information of the prompt unit 60 is transmitted to the operator through the visual window 321. The visible window 321 is formed on the rear side of the lamp head 32. When the curing lamp is used by the operator in a hand-held manner, the visible window 321 faces the operator for easy operation The person observes the prompt unit 60 through the visual window 321. Exemplarily, when the prompt unit 60 is a display screen, the operator observes the information displayed by the prompt unit 60 through the visual window 321, so that the operator can operate or adjust the information according to the prompt information of the prompt unit 60 The working status of the curing lamp.

Preferably, the lamp head 32 and the handle portion 33 of the lamp housing 30 are an integrated structure, wherein the lamp head 32 and the handle portion 33 form a containing cavity 322, wherein the control The processor 22 and the circuit board 23 of the system 20 are held in the containing cavity 322. The control switch 21 of the control system 20 is arranged on the handle portion 33 so that the operator can control the control switch 21 of the control system 20 in a handheld manner with one hand when operating the curing lamp. Preferably, the control switch 21 is arranged at the upper end of the handle portion 33, wherein the control switch 21 faces the light irradiation direction of the curing lamp. It can be understood that the position where the control switch 21 is installed is only exemplary here, and not a limitation.

The lamp holder part 34 of the lamp housing 30 is disposed under the handle part 33, and the handle part 33 and the lamp head 32 are supported by the lamp holder part 34. Preferably, the lamp holder part 34 integrally extends from the handle part 33. The lamp holder part 34 can be used to support the curing lamp to maintain an upright state and continuously irradiate the coating 100. In other words, the lamp holder portion 34 of the curing lamp can be placed or fixed on a supporting frame or a supporting plane, and the lamp holder portion 34 maintains the irradiation state of the curing lamp. It is understandable that by adjusting the fixing position of the lamp holder part 34 of the curing lamp, the irradiation distance between the curing lamp and the coating 100 is adjusted, and by adjusting the placement angle of the lamp holder part 34 Or the supported angle, and adjust the light irradiation direction of the light source 10 of the curing lamp.

It is worth mentioning that in this preferred embodiment of the present invention, the lamp holder portion 34, the handle portion 33, and the lamp head 32 of the lamp housing 30 form a "匚"-shaped support structure. The operator can operate the lamp housing 30 of the curing lamp by hand.

As shown in FIGS. 2 to 4B, the lamp housing 30 further includes a first housing 35 and a second housing 36, wherein the first housing 35 and the second housing 36 are buckled with each other. Connected, wherein the upper ends of the first housing 35 and the second housing 36 form the lamp head 32 of the lamp housing 30, and the first housing 35 and the second housing 36 The lower end of the lamp housing 30 forms the socket portion 34 of the lamp housing 30. The middle part of the first housing 35 and the second housing 36 forms the handle portion 33, and the handle portion 33 connects the lamp head 32 to the lamp socket portion 34.

The battery 81 of the power supply system 80 is stored in the lamp holder part 34, wherein the lamp holder part 34 has at least one battery cavity 341, and the lamp holder part 34 stores the battery 81 in the lamp holder part 34. In the battery cavity 341. The external power supply device 82 can be electrically connected to an external power supply, and transmit the power of the external power supply to the battery 81 of the power supply system 80, or to the curing lamp via the circuit board 23. Other electrical components. Correspondingly, the power supply external device 82 further includes a direct charging unit 821 and at least one charging unit 822, wherein the direct charging unit 821 is electrically connected to the external power supply to the circuit board 23 of the control system 20, wherein The direct charging unit 821 transfers the electrical energy of the external power supply to the electrical components of the curing lamp, such as the light source 10, through the circuit board 23. That is to say, when the direct charging unit 821 of the curing lamp is electrically connected to an external power source, the electric energy of the external power source is transmitted to the power consumption units of the curing lamp through the direct charging unit 821. It is understandable that the circuit board 23 can also store the electric energy obtained by the direct charging unit 821 to the battery 81. In short, the external power supply can directly function as the curing lamp through the direct charging unit 821. In particular, when the curing lamp works for a long time, the direct charging unit 821 can provide the curing lamp with working electric energy. Preferably, the opening of the direct charging unit 821 is arranged toward the rear of the lamp housing 30.

The dock charging unit 822 is electrically connected to the battery 81, wherein an external power source or other charging device charges the battery 81 through the dock charging unit 822.

As shown in FIGS. 2 and 6, the curing lamp further includes at least one base 90, wherein the lamp housing 30 of the curing lamp can be set on the base 90 and supported by the base 90 And the lamp housing 30 that holds the curing lamp for the storage and storage of the curing lamp. When the lamp housing 30 of the curing lamp is placed on the base 90, the base 90 can charge the battery 81 of the curing lamp through the base charging unit 822. In other words, the base 90 can be used to house and store the lamp housing 30, the control system 20, and the light source 10 of the curing lamp. The lamp housing 30 of the chemical lamp is fixed by the base 90 to maintain the light irradiation distance and light irradiation angle between the light source 10 and the coating 100 of the curing lamp. The base 90 can also be energized to connect an external power supply to the base charging unit 822 of the power supply system 80, and the base charging unit 822 charges the battery 81.

In detail, the base 90 includes a base main body 91 and at least one receiving cavity 92 formed by the base main body, wherein the lamp socket portion 34 of the housing 30 can be used by the base main body. 91 is stored in the storage cavity 92. It can be understood that the shape of the receiving cavity 92 of the base 90 is adapted to the lamp holder portion 34. The base 34 further includes a locking device 93, wherein when the lamp holder portion 34 of the housing 30 is placed on the locking device 93, the locking device 93 can hold the lamp holder The portion 34 is locked to the receiving cavity 92. The locking device 93 is movably arranged below the base body 91. Preferably, the locking device 93 is locked under the lamp holder portion 34 in a snap-fit manner. The locking device 93 further includes a locking member 931, an unlocking member 932, and a resetting device 933, wherein the locking member 931 is disposed on the unlocking member 932, and the locking member 931 protrudes inwardly于The base body 91. When the lamp socket part 34 of the lamp housing 30 is placed in the receiving cavity 92, the front end of the lamp socket part 34 pushes the engaging member 931 to rotate downward, and is buckled with the lamp socket部34. The engaging member 931 is arranged at the upper end of the unlocking member 932, and the engaging member 931 can be separated from the lamp holder part 34 by operating the unlocking member 932, so as to separate the lamp housing 30 from the Take out from the base 90. The resetting device 933 supports the engaging member 931 of the locking device 93 to be held in the receiving cavity 92.

Correspondingly, the lamp holder portion 34 is further provided with at least one slot 342, wherein the slot 342 is formed under the lamp holder portion 34. When the lamp holder part 34 is placed in the receiving cavity 92 of the base 90, the locking device 93 of the base 90 is locked with the slot 342 of the lamp holder part 34 , To prevent the lamp housing 30 from detaching from the base 90.

The base 90 can be installed on a bracket, such as a tripod, or fixedly installed on a surface of a support such as a wall or a desktop. The base 90 further includes at least one connecting piece 94, wherein the connecting piece 94 is disposed below the base body 91, and the connecting piece 94 connects the base body 91 to the attached object. surface.

The base 90 further includes at least one charging unit 95, wherein the charging unit 95 can be electrically connected to an external power source, and the charging unit 95 can store the electrical energy of the external power source to all of the power supply system 80. Mentioned battery 81. The charging unit 95 can supply power to the battery 81 through a wireless charging method or an electrical contact charging method. Exemplarily, when the lamp housing 30 of the curing lamp is stored in the base 90, the charging unit 95 is electrically connected to the base charging unit 822, and the charging unit 95 transmits electric energy to the base 90. The base charging unit 822 stores electric energy in the battery 81 through the base charging unit 822.

As shown in Figure 9, the curing lamp can automatically collect the coating information of the coating 100, so that the control system 20 can obtain suitable drying and curing of the coating 100 based on the coating information of the coating 100 Information such as curing time, light intensity, and irradiation distance. The curing lamp further includes a paint collection device 51, wherein the paint collection device 51 collects the paint information of the coating layer 100 and transmits the paint information to the control system 20 for the control system 20 At least one curing control scheme is generated based on the coating information. The paint collection device 51 is communicatively connected to the curing setting unit 50, wherein the paint collection device 51 transmits the collected paint information to the curing setting unit 50, and the curing setting unit 50 sets the The control parameters for transmitting the curing control data information to the processor 22 of the control system 20.

According to another aspect of the present invention, the present invention further provides a curing control method of a curing lamp, wherein the curing control method includes the following steps:

(a) Detect the distance between the curing lamp and a coating 100 being irradiated; and

(b) Obtain curing data information of the coating 100 being cured based on the distance between the curing lamp and the coating 100, and control the working state of a light source 10 of the curing lamp according to the curing data information.

In the step (b) of the above-mentioned curing control method of the present invention: the curing data information of the coating includes any combination of factors consisting of light intensity, light time, curing area, and irradiation distance. Before the step (b) of the above-mentioned curing control method of the present invention, it further includes: inputting the paint information of the cured coating 100, wherein the paint information includes the paint type of the coating 100 and the The coating thickness of the coating 100. In the step (b) of the above-mentioned curing control method of the present invention, an illumination intensity of the curing lamp is set, and the illumination time of the curing lamp is controlled according to the irradiation distance of the curing lamp. In the step (b) of the above curing control method of the present invention, an illumination time of the curing lamp is set, and the light intensity of the light source 10 of the curing lamp is controlled according to the irradiation distance of the curing lamp . In the step (b) of the above-mentioned curing control method of the present invention, the irradiation distance of the curing lamp to the coating 100 is set based on the curing area of the coating 100, and according to the curing lamp The irradiation distance controls the light intensity and irradiation time of the light source 10 of the curing lamp.

After the step (a) of the curing control method of the present invention, the method further includes the step of displaying the irradiation distance information of the curing lamp based on the detected distance, so as to prompt the operator to operate the curing lamp according to the prompt information. After the step (b) of the curing control method of the present invention, the method further includes a step (c) based on the obtained curing data information of the coating 100, displaying the working status of the work lamp in real time.

In the step (a) of the above-mentioned curing control method of the present invention, it further includes the step of detecting the distance between the light source 10 and the coating 100 by means of ultrasonic detection. Correspondingly, the step (a) further includes: transmitting a probe ultrasonic wave and receiving an echo of the probe ultrasonic wave; and obtaining the light source 10 based on the transmitted probe ultrasonic wave and the received echo The distance from the coating 100.

Those skilled in the art should understand that the above description and the embodiments of the present invention shown in the accompanying drawings are only examples and do not limit the present invention. The purpose of the present invention has been completely and effectively achieved. The functions and structural principles of the present invention have been shown and explained in the embodiments. Without departing from the principles, the embodiments of the present invention may have any deformation or modification.

Claims (42)

1. A curing lamp, suitable for curing a coating by irradiation, is characterized in that it includes:

   At least one light source;

   A lamp housing; wherein the light source is provided in the lamp housing; and

   A distance detection device, the distance detection device is arranged on the lamp housing, and the distance detection device detects the irradiation distance of the light source irradiated to the coating.
2. The curing lamp of claim 1, further comprising a control system, wherein the power source is electrically connected to the control system, the distance detection device is communicatively connected to the control system, and the control system is configured To control the working state of the light source based on the irradiation distance detected by the distance detecting device.
3. The curing lamp according to claim 2, wherein the light source and the distance detecting device are fixedly installed in the lamp housing, and the distance detecting device is adjacent to the light source in the same direction The ground is disposed on the light source, whereby the distance detecting device detects the distance between the light source and the coating.
4. The curing lamp according to claim 2, wherein the distance detecting device is selected from the group consisting of an ultrasonic distance detecting device, an infrared distance detecting device, and a laser distance detecting device.
5. The curing lamp according to claim 2, wherein the distance detecting device includes an ultrasonic generating device, an ultrasonic receiving device, and an ultrasonic processing device, and the ultrasonic processing device is communicably connected to the ultrasonic generating device and In the ultrasonic receiving device, the ultrasonic processing device is configured to obtain the ultrasonic detection signal based on an ultrasonic detection signal emitted by the ultrasonic generating device and a detection echo of the ultrasonic detection signal received by the ultrasonic receiving device The irradiation distance between the light source and the coating.
6. The curing lamp according to claim 2, wherein the control system includes a circuit board and a processor, wherein the light source is electrically connected to the processor through the circuit board, and the distance detecting device is communicatively connected to The processor, the distance detection device transmits the detected illumination distance information to the processor, and the processor controls the light intensity of the light source based on the illumination distance.
7. 7. The curing lamp according to claim 6, wherein the control system further comprises a control switch, the control switch is electrically connected to the circuit board, and the control switch controls the on and off of the light source through the circuit board.
8. The curing lamp according to claim 6, wherein the light source comprises at least one curing light unit and a light source controller, wherein the curing light unit is electrically connected to the circuit board of the control system by the light source controller , The light source controller controls the curing light unit based on the electrical signal transmitted by the circuit board.
9. The curing lamp according to claim 6, further comprising a curing setting unit, wherein the curing setting unit can set a curing data parameter to the processor, and the processor controls the light source based on the curing data parameter Working status.
10. The curing lamp according to claim 9, wherein the curing setting unit is used to input the coating data information to the processor, wherein the processor controls the illumination of the light source based on the coating data information Time and light intensity.
11. The curing lamp according to claim 6, wherein the curing lamp further comprises a prompt unit, wherein the prompt unit is communicatively connected to the distance detection device, and the distance detection device transmits the detected distance information to the The prompt unit prompts the irradiation distance of the curing lamp.
12. 11. The curing lamp according to claim 11, wherein the prompt unit is communicatively connected to the control system, and the processor of the control system transmits working status information of the curing lamp to the prompt unit.
13. The curing lamp according to claim 9, wherein the curing setting unit sets curing time and inputs coating data information to the processor, and the processor is based on the data information set by the curing setting unit and the The illumination distance information collected by the distance detection device controls the light intensity of the light source.
14. The curing lamp according to claim 9, wherein the curing setting unit sets light intensity and inputs coating data information to the processor, and the processor is based on the data information set by the curing setting unit and the The illumination distance information collected by the distance detection device controls the illumination time of the light source.
15. The curing lamp according to claim 9, wherein the curing setting unit sets the curing irradiation area of the curing lamp and inputs the coating data information to the processor, and the processor is based on the curing irradiation area Obtain the illumination distance information of the curing lamp, and control the illumination intensity and illumination time of the light source according to the change of the illumination distance.
16. The curing lamp according to claim 9, wherein the curing lamp further comprises at least one paint collecting device, the paint collecting device collects paint information of the cured coating, and the paint collecting device is communicatively connected to the curing The curing setting unit of the lamp, wherein the paint collecting device transmits the collected paint information to the curing setting unit.
17. 3. The curing lamp of claim 3, wherein the curing lamp further comprises a heat dissipation device, wherein the light source is disposed adjacent to the heat dissipation device, so that the heat dissipation device reduces the temperature of the light source.
18. 17. The curing lamp of claim 17, wherein the heat dissipating device comprises a heat conducting device, wherein the light source is connected to the heat conducting device in a thermally conductive manner, and the heat generated by the light source is conducted to the heat conducting device.
19. The curing lamp according to claim 18, wherein the heat conduction device has a heat conduction cavity and at least one set of heat dissipation channels connecting the outside to the heat conduction cavity, wherein the light source is arranged in the heat conduction cavity by the lamp housing, The heat in the heat dissipation channel is conducted to the external environment through the heat dissipation channel.
20. The curing lamp according to claim 19, wherein the heat conducting device further comprises an air cooling device, wherein the air cooling device is disposed in the heat conducting cavity of the heat conducting device, and the air cooling device is electrically connected to the In the circuit board, the air cooling device blows air in the heat conduction cavity to accelerate the air convection between the heat conduction cavity and the external environment.
21. The curing lamp according to any one of claims 2 to 17, wherein the lamp housing includes a lamp cover and a lamp head, wherein the lamp cover fixes the light source and the distance detecting device to the heat sink, The heat dissipation device is arranged in front of the lamp head, and the lamp head maintains the light irradiation direction of the light source by supporting the heat dissipation device.
22. The curing lamp according to claim 21, wherein the lamp head further has a visible window formed on the rear side of the lamp head, wherein the prompt unit is provided on the lamp The visible window of the head.
23. The curing lamp according to claim 21, wherein the lamp housing further comprises a handle portion and a lamp holder portion, wherein the handle portion extends downward from the rear side of the lamp head, and the lamp holder portion is located at the Below the handle portion, wherein the lamp holder portion supports the lamp head through the handle portion, and the handle portion is adapted to be gripped and operated.
24. 22. The curing lamp of claim 21, wherein the curing lamp further comprises a power supply system, wherein the power supply system is electrically connected to the circuit board of the control system for the circuit board to supply the power supply and The distance detection device is powered.
25. The curing lamp according to claim 24, wherein the power supply system comprises a battery and at least one external power supply device, wherein the external power supply device is electrically connected to the battery, and the external power supply device can charge the battery.
26. The curing lamp according to claim 25, wherein the external power supply device further comprises a direct charging unit, wherein the direct charging unit is electrically connected to the circuit board, and the direct charging unit provides electric energy to the circuit board through the circuit board. The light source and the distance detection device.
27. 26. The curing lamp of claim 26, wherein the direct charging unit is disposed on the lower side of the lamp housing, and the charging opening of the direct charging unit faces the rear of the curing lamp.
28. 22. The curing lamp of claim 25, wherein the external power supply device further comprises a charging unit, wherein the base charging unit is electrically connected to the battery, and the base charging unit can store electrical energy to the battery.
29. The curing lamp according to claim 28, wherein the socket charging unit is disposed under the lamp socket part of the lamp housing.
30. The curing lamp according to claim 23, wherein the curing lamp further comprises at least one base, wherein the lamp housing of the curing lamp can be stored in the base, and the base is received and supported by The curing lamp.
31. The curing lamp according to claim 28, wherein the curing lamp further comprises at least one base, wherein the lamp housing of the curing lamp can be stored in the base, and the base is received and supported The curing lamp.
32. 30. The curing lamp according to claim 30, wherein the base includes a base body and further has at least one storage cavity, wherein the lamp holder portion of the curing lamp can be received by the base body to the Storage cavity.
33. The curing lamp according to claim 32, wherein the base further comprises a locking device, the locking device is movably disposed on the base body, and the lamp holder portion of the curing lamp has at least A card slot, when the lamp holder part of the curing lamp is received in the receiving cavity, the locking device is engaged with the card slot of the lamp holder part to restrict the lamp holder part Mobile.
34. The curing lamp according to claim 31, wherein the base further comprises at least one connecting member, wherein the connecting member is disposed below the main body of the base, and the connecting member connects the base to a support Things.
35. The curing lamp according to claim 31, wherein the base further comprises at least one charging unit, the charging unit is arranged under the charging body, when the lamp holder part of the curing lamp is received in the In the storage cavity, the charging unit is electrically connected to the base charging unit, and the battery is charged by the base charging unit.
36. A curing control method for curing lamps, characterized in that, the curing control method includes the following steps:

    (a) Light irradiates a coating and detects the irradiation distance between a light source and the coating; and

    (b) Obtain curing data information of the coating being cured based on the detected irradiation distance, and adjust the working state of a light source of the curing lamp according to the curing data information.
37. The curing control method according to claim 36, wherein before the step (b) of the curing control method, it further comprises: obtaining paint information of the cured coating, wherein the paint information includes the coating The coating type of the layer and the coating thickness of the coating.
38. The curing control method according to claim 37, wherein in the step (b) of the curing control method, a light intensity of the curing lamp is set, and the curing is controlled according to the irradiation distance of the curing lamp The light time of the lamp.
39. The curing control method according to claim 37, wherein in the step (b) of the curing control method, an illumination time of the curing lamp is set, and the curing lamp is controlled according to the irradiation distance of the curing lamp The light intensity of the light source.
40. The curing control method according to claim 37, wherein in the step (b) of the curing control method, the irradiation distance of the curing lamp to the coating is set based on the cured area of the coating, And controlling the light intensity and the irradiation time of the light source of the curing lamp according to the irradiation distance of the curing lamp.
41. The curing control method according to claim 36, wherein the step (a) of the curing control method further comprises the step of displaying the irradiation distance information of the curing lamp based on the detected distance to remind the operator to follow the prompt Information to operate the curing lamp.
42. The curing control method according to claim 41, wherein the step (b) of the curing control method further comprises the step (c) based on the obtained curing data information of the coating, displaying in real time the working light Working status.

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