CN219036539U - Intelligent phototrophic device - Google Patents

Abstract

The utility model relates to an intelligent phototrophic device, which comprises a base, a supporting unit, an intelligent control unit and a phototrophic unit, wherein the base is provided with a light source; the top of the base is connected with a supporting unit, and the top of the supporting unit supports the phototrophic unit; the light nutrition unit comprises a plurality of lamp groups, wherein the lamp groups enable the illumination of an illumination area to be adjustable within 800-30000 lux; the control unit is arranged on at least one of the base, the supporting unit and the phototrophic unit and comprises a plurality of light control modules for controlling the lamp groups of the phototrophic unit to be switched between different illumination modes. The intelligent phototrophic device has the advantages of simple structure, multiple functions and convenient use, embodies the advanced phototrophic concept of phototrophic and scientific light, is environment-friendly, and can effectively improve the living and health level of people.

Description

Intelligent phototrophic device

Technical Field

The utility model belongs to the technical field of intelligent optical application, in particular to an intelligent optical device, and particularly relates to an intelligent phototrophic device.

Background

Light has a very important effect on the physiology of organisms, and humans have long begun to study the important effect of light on plant growth, and have gradually found that light has a great effect on animals, particularly mammals, including but not limited to direct or indirect effects on the thermal energy metabolism, behavior, life cycle, etc. of animal organisms, and has been used in the technical fields of biological genetic engineering, medicine, agriculture and forestry, environmental science, livestock, aquatic products, etc. such as the use of light to regulate the growth, reproduction, feeding, breed screening, etc. of animals such as birds, fish, cattle and sheep, etc.

For mammals, including humans, it has been demonstrated that light regulates a range of physiological processes, including sleep-wake, core body temperature, metabolism, fluctuations in gene expression, and hormone production, which are important for maintaining physiological homeostasis of an organism. However, after entering modern society, the time of human being in the room gradually exceeds the outdoor time, and the lighting equipment is widely applied, and the quality of illumination greatly influences the living and health level of human beings. Animal experiments prove that a series of diseases such as obesity, diabetes, insulin resistance, lipid metabolism disorder and the like can be caused by long-time exposure to artificial light at night, which shows that the light irradiation has close connection with the occurrence and the development of metabolic diseases. For example, the task group Liu Chang of the national academy of medical science and technology has conducted intensive studies on the effect of light color on metabolism of mammals, and the task results are described in Chronic exposure to green light aggravates high-fat set-induced obesity and metabolic disorders in male mice: mice exposed to green light for a long period of time accelerate the progress of obesity in mice caused by a high-fat diet, giving them poorer glucose tolerance and higher serum and liver lipid levels. In addition, melatonin receptor 1-b and thyroid hormone receptor β expression levels were also significantly reduced in liver tissue of green light treated obese mice, suggesting that these hormone pathways may be involved in the regulation of lipid metabolism.

With the progressive penetration of photonics research, techniques for regulating physiological functions of human beings using healthy light are widely used in the medical field, such as: (1) The treatment of hyperbilirubinemia or jaundice in very low birth weight infants by LED blue light or ordinary blue light irradiation is well established, and blue light beds and phototherapy boxes have been widely used in gynaecology and obstetrics, for example US08202307B2, CN203663256U, etc. (2) In recent years, treatment of patients with Alzheimer's disease accompanied by sleep disturbance by full spectrum light irradiation has been studied intensively, for example, CN109499003A and the like. (3) The ultraviolet irradiation is used for treating vitiligo, psoriasis, onychomycosis, etc., such as EP2236150A1, CN215995312U, etc. (4) The light is used for intervening in mental diseases such as depression, or treating insomnia, for example, JP2008245836A, CN2643913Y, etc. However, the above-mentioned prior arts use a single spectrum of artificial light to intervene in a specific disease, and thus the prior arts have narrow application fields and are difficult to popularize in a large scale.

In 2002, david Berson et al, university of Brown, united states found on the retina of mice, a third photoreceptor cell, retinal ganglion photoreceptor cells (ipRGCs), in addition to rod cells and cone cells, breaking the concept that the human eye only had visual channels, an important finding that was evaluated by Science as one of ten major findings in the world of the current year. It is found that the photoreceptor cell accounts for about 25% of the retinal nerve cells, and can transmit non-visual light signals to the pineal gland of hypothalamus to participate in the regulation of biological clock, so as to generate human photo-biological effect, thereby affecting the physiology, memory, physiological health and the like of human body. Unlike conventional vision transmission processes, the photo-biological effect process is to transmit light signals from the retinal ganglion photoreceptor cells (ipRGCs) to the hypothalamic pathway (RHT) and then to the hypothalamic nucleus such as the upper optic nerve crossing nucleus (SCN) and the paraventricular nucleus (PVN). The supraoptic nucleus transmits both optical and non-optical information to various control centers of the nervous system, thereby regulating physiological signs such as circadian rhythms, body temperature, heart rate, and the like, as well as the production of nearly all hormones including cortisol, melatonin, membrane islets, growth hormone, and the like. In 2017, the scientific and technological department of China also has the standing to initiate a national key research and development plan, namely 'photo-biological mechanism and application research facing to healthy illumination'.

Based on the above principle, the illumination health device using the non-visual photo biological effect is also gradually applied in daily life: patent CN211215019U discloses a phototherapy garment with LED lamp beads, which is used for solving the problems of less sun exposure of modern people, high cost of phototherapy equipment, inapplicability to household use and the like; patent CN201020163Y discloses a phototherapy lamp which is easy to fix on furniture such as a table, a bedstead, a chair back and the like, is convenient to fix and adjust angles, and can realize physiotherapy of skin diseases at home; patent CN201328925Y discloses a visual phototherapy apparatus, which uses three-color light to alternately flash and stimulate cone cells, activate visual system and promote visual development.

However, the above-mentioned phototrophic products in the prior art have great difference from natural light, single action, inconvenient use, and narrow spectrum band, and can not completely meet the needs of people for healthy illumination. When humans are in an indoor environment for longer and longer, the light level is only a small part of the sunlight level; and at night, the situation is just opposite due to light pollution caused by electronic products, street lamps, car lamps and neighborhood light rays.

Therefore, how to effectively utilize the photo-biological effect, and to obtain a photo-nutritional device which is close to natural light and has controllable light performance in indoor daily illumination so as to meet various requirements of people on photo-nutrition is a technical problem to be solved in the field.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide an intelligent phototrophic device which has a simple structure and is convenient to use, the provided intelligent light is close to natural light, has various functions, effectively utilizes the photo-biological effect, adjusts the rhythm of a human body and improves the living and health level of people.

Specifically, the utility model provides an intelligent phototrophic device, which comprises a base, a supporting unit, an intelligent control unit and a phototrophic unit;

the top of the base is connected with a supporting unit, and the top of the supporting unit supports the phototrophic unit;

a phototrophic unit comprising a plurality of lamp groups, wherein the lamp groups enable the illumination intensity of an illumination area to be adjusted within 800-30000 lux;

the intelligent control unit is arranged on at least one of the base, the supporting unit and the phototrophic unit;

the intelligent control unit comprises a plurality of light control modules for controlling the lamp groups of the light nutrition unit to switch between different illumination modes.

The phototrophic unit is designed to be capable of adjusting the illumination of an illumination area to be 800-30000lux, preferably 1000-15000lux continuously, so that the illumination can cover the illumination of natural light, simulate the outdoor natural light environment and make up for the defect that people usually move indoors and cannot receive natural light; on the basis, the illumination can cover a wider adjustable range, can be flexibly adjusted by people, and can meet various functions such as calcium supplement, beauty treatment and the like. The irradiation area related to the light nutrition unit comprises an area from the light emitting surface to an irradiation plane of the light nutrition unit lamp group, wherein the irradiation plane is parallel to the light emitting surface, and the vertical distance from the irradiation plane to the light emitting surface is 50-100cm, preferably 50-80cm, more preferably 60-70cm; the illuminance value of the illumination area is preferably the result of illuminance detection of the center of the illumination plane.

The control unit preferably comprises at least three-gear light control modules, more preferably comprises at least four-gear light control modules, and the lamp groups of the light nutrition unit are controlled to be switched between different illumination modes, so that the illumination of an illumination area can be freely switched to adapt to different scenes and different crowds.

Further, the base comprises a battery and a charging interface thereof, and the battery is electrically connected with the control unit. According to the utility model, the battery, such as a rechargeable battery such as a lithium battery, is arranged in the base, so that various wired and wireless application scenes can be met, and the service life of the phototrophic device is prolonged by using the detachable and replaceable lithium battery.

Further, the bottom of base sets up the gyro wheel, the gyro wheel with intelligent control unit signal connection, the gyro wheel is directional wheelset, universal wheelset or combination thereof to can adjust the direction of movement of whole device with little effort. The intelligent control type base is adopted, so that the phototrophic device is convenient to move, and the working range of the phototrophic device is enlarged. The intelligent control mode can adopt various control modes existing in the prior art, such as voice or password control, remote control key control and the like.

Further, the supporting unit comprises a telescopic supporting rod below and a connecting component above; the telescopic supporting rod is detachably connected to the base, and the connecting component is connected with the phototrophic unit and drives the phototrophic unit to move and position in a three-dimensional space.

The lamp group of the light nutrition unit is formed by combining a plurality of detachable lamp group modules, and when the light nutrition unit is used, the quantity, the irradiation angle or the power and other conditions can be matched and adjusted according to actual requirements. The number of the lamp group modules is preferably 3-5 according to the factors of the structure, the function, the cost and the like, and when the lamp group modules are aged or damaged, the lamp group modules can be conveniently taken down and replaced. Each lamp group module comprises a plurality of lamp sources, wherein the lamp sources are LED lamps, laser lamps or a combination of the LED lamps and the laser lamps, and the LED lamps, the laser beads or the combination of the laser lamps can be provided with different powers for each lamp group module according to use requirements.

Further, the intelligent control unit comprises a control console arranged in the middle of the supporting unit, and the control console is respectively connected with the telescopic supporting rod below and the connecting component above. By means of the arrangement of the control console, a connecting platform is formed in the middle of the supporting unit, and more interfaces and function expansion modes are provided for the phototrophic device. In addition, according to the design requirement, the control console can be designed as a simple component in the supporting unit, and the function control of the phototrophic device can be realized.

For the specific composition and connection mode of the connection assembly, preferably, the connection assembly comprises a first rotating arm and a second rotating arm, one end of the first rotating arm is rotatably installed on the console, the second rotating arm is rotatably connected to the other end of the first rotating arm, and the phototrophic unit is rotatably installed at the end part of the second rotating arm far away from the first rotating arm. In order to ensure rotational stability, the second rotating arm may optionally use the first rotating arm as a rotation axis. By arranging the two rotating arms, the rotatable range of the phototrophic unit is obviously expanded and is close to 360 degrees in front and back, the position can be flexibly changed, and the requirements of different illumination positions are met.

Further, the light nutrition unit comprises a connecting part and a mounting part rotationally fixed with the connecting part, the connecting part is rotationally connected with the end part of the second rotating arm far away from the first rotating arm, and the mounting part is used for fixing the lamp group. In order to ensure rotation stability, the connecting part can optionally rotate relative to the second rotating arm by taking the axis of the connecting part as a rotating shaft; and, because the installation department will bear more banks, there is great heavy burden demand, and the front end design of connecting portion is U type structure, and a supporting end is established respectively to U type structure front end inboard, inserts the mounting hole that two sides of installation department correspond respectively and carries out the connection support to two supporting end lines are the rotation axis, the installation department can rotate with the adjustment irradiation angle along this rotation axis. Through above-mentioned setting, the phototrophic unit has more various irradiation positions and angles, better satisfies the demand of shining the object. In addition, the plurality of lamp group modules are respectively and detachably and rotatably fixed on the mounting part, the arrangement mode of the lamp group modules is various and selectable according to actual irradiation requirements, shape design of the mounting part and the like, for example, when a disc-shaped mounting part is adopted, the lamp group modules can be radially distributed and mounted; when the strip-shaped installation part is adopted, the lamp group modules can be installed in a linear arrangement mode or in a mixed installation mode, so that the lamp group modules can provide irradiation modes with multiple angles and multiple modes for an irradiation area.

The device also comprises an illumination sensor, wherein at least one parameter of illuminance, color temperature, color rendering index and peak wavelength of the illumination area is monitored, and a monitoring result is sent to a receiving module of the control unit to realize the light monitoring function of the illumination area; and the control unit compares the preset mode parameters according to the monitoring result, rapidly adjusts parameters such as the irradiation quantity or the power of the lamp group of the phototrophic unit, and adjusts the light parameters of the irradiation area to the preset parameters conforming to the setting module. Among the plurality of light parameters, it is preferred to monitor at least the illuminance of the illumination region. The illumination sensor may be arranged at a plurality of positions of the phototrophic apparatus, preferably at the support unit.

The device also comprises a lighting device which is electrically connected to at least one of the base, the supporting unit and the phototrophic unit through a flexible supporting arm and is controlled by a lighting module of the intelligent control unit.

The utility model has the advantages that:

(1) The illumination intensity of the intelligent phototrophic device is arbitrarily and continuously adjustable at 800-30000lux, a plurality of functional modules such as light control and the like are covered, the width and the height of the illumination intensity are also covered, and the intelligent phototrophic device is a general illumination device on a far supermarket surface. Fully utilizes the effects of light energy in health care, health preservation, conditioning and the like, further digs the optical potential, and provides an advanced phototrophic concept of phototrophic and scientific light, thereby being green and environment-friendly and having wide prospect.

(2) At least four phototrophic modes are provided, different spectrum scientific configurations are provided, the use requirements of different members of families are met, and intelligent personalized setting space and hardware support are provided.

(3) The base is intelligent and movable, so that the mobile use is convenient; and a rechargeable lithium battery is built in, so that the multi-scene use convenience is provided.

(4) The flexible adjusting mode of the supporting unit and the connecting unit meets the application requirements of multiple scenes and multiple types of people.

Drawings

FIG. 1 is a front view of a phototrophic apparatus of the present utility model;

figure 2 is a side view of the phototrophic apparatus of the present utility model;

fig. 3 is a schematic view of another embodiment of a phototrophic unit mount.

Reference numerals illustrate: 1. base, 2, phototrophic unit, 21, connecting portion, 211.U type support arm, 212, first telescopic arm, 213, second telescopic arm, 214, rotation fixed portion, 22, installation portion, 23, lamp group module, 3, control console, 4, telescopic support bar, 5, first rotary arm, 6, second rotary arm.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the present utility model will be described in further detail with reference to the following examples and the accompanying drawings.

As shown in fig. 1 to 3, an intelligent phototrophic apparatus includes a base 1, a support unit, an intelligent control unit, and a phototrophic unit 2; the top of the base 1 is connected with a supporting unit, and the top of the supporting unit supports the phototrophic unit 2; the phototrophic unit 2 comprises a connecting part 21, a mounting part 22, a plurality of lamp groups carried by the mounting part 22, a lens, a cover body and other components, wherein the lamp groups are formed by combining a plurality of detachable lamp group modules 23, each lamp group module 23 comprises a plurality of lamp sources, and the lamp sources are LED lamps, laser lamps or the combination of the LED lamps and the laser lamps. The light nutrition unit 2 is capable of emitting light which makes the illumination of the center of the illuminated area 800-30000lux, preferably 1000-15000lux, at a standard height of 1-3 m. The prior art generally adopts illumination standard of 100-500lux only in common workplaces (as described in illumination GB/T26189-2010 of indoor workplaces, traffic areas and hallways, rest rooms, machine rooms, shops, warehouses, cold houses and the like of general buildings should reach illumination of 100lux, illumination of dining halls, clothes rooms, toilets, bathrooms and the like should reach illumination of 200lux, illumination of medical rooms, transceiving rooms, distribution rooms and the like should reach illumination of 500lux, illumination of 500lux of other buildings such as reading rooms of libraries, illumination of 300lux of classrooms/coaches of educational buildings and the like). The intelligent phototrophic device has 800-30000lux illuminance, and the width and the height of the illuminance are far more than those of a light emitting device commonly adopted in the prior art. The illumination is continuously adjustable, and is different from the single function of a common lighting device, the phototrophic device provided by the utility model enables illumination to cover a wider adjustable range, and can selectively provide the optimization functions of phototrophic categories such as cosmetology, calcium supplement and the like on the basis of meeting the requirements of providing natural illumination (see the total direct illumination and the total scattered illumination of typical cities in China shown in Table 1).

TABLE 1 Total direct and scattered illumination for typical cities in China (data Source: statistics of 83/84 year observations)

The light emitting means of the light nutrition unit 2, such as a lamp set, may be combined from a plurality of detachable lamp set modules 23, preferably 3-50 lamp set modules 23 are used depending on the number and performance of the lamp sources of the lamp set modules 23 themselves. The lamp group module 23 is too few, the number of the lamp sources carried by the single lamp group module 23 is larger, the size is larger, the production and maintenance cost is too high, and the angle adjustment is limited; the light group module 23 is too many, and the structural complexity of the phototrophic unit 2 promotes, and overall weight is off-high, increases the connecting unit and supports and adjust the degree of difficulty. When the lamp group module is used, the quantity and the power of the lamp group module 23 can be matched and adjusted according to actual requirements. For example, when stronger illumination is needed, a white light module can be added; when the color temperature needs to be regulated, the blue light/red light/green light module can be increased or reduced in a targeted manner; if a specific illumination mode such as ultraviolet illumination is required, an ultraviolet module can be added, and 20% of ultraviolet light can be added for a myopic user, so that the myopia can be effectively prevented and controlled; for other different users, the number, intensity and illumination of the spectrums can be increased and reduced as required according to different illumination of the spectrums, so that various maintenance purposes can be achieved. In addition, the arrangement mode of the lamp group modules 23 is various and optional according to the actual irradiation requirement, the shape design of the mounting part 22, and the like, for example, when a disk-shaped mounting part is adopted, the lamp group modules can be arranged in a radial distribution (see fig. 2); when the strip-shaped mounting part is adopted, the lamp group modules can be arranged in a linear mode (see fig. 3), or in a mixed mounting mode, so that the lamp group modules can provide irradiation modes with multiple angles and multiple modes for an irradiation area.

The mounting portion 22 of the phototrophic unit 2 may be in the form of a mounting table or a mounting groove, and the lamp set is fixed on one side of the mounting portion 22. The other side of the mounting portion 22 may be connected to the connection portion 21 by means of a snap connection, hinge, welding, screw connection, etc., and connected to the supporting unit through the connection portion 21 to fix the phototrophic unit 2. The connection part 21 is rotatably connected with the second rotating arm 6 of the upper connection assembly of the supporting unit to adjust the angle of the light and nutrition unit 2.

The front end of the connecting part 21 is designed into a U-shaped supporting arm 211, the rear end is designed into a U-shaped supporting arm 211 comprising a first telescopic arm 212, a second telescopic arm 213 and a rotation fixing part 214 rotationally connecting the first telescopic arm 212 and the second telescopic arm 213, the first telescopic arm 212 is rotationally connected with the second rotating arm 6, and the second telescopic arm is rotationally connected with the front end. The inner sides of the front ends of the U-shaped supporting arms 211 are respectively provided with a supporting end, the supporting ends are respectively inserted into the corresponding mounting holes on the two side surfaces of the mounting part 22 for connection and support, the connecting line of the two supporting ends is taken as a rotating shaft, and the mounting part 22 can rotate along the rotating shaft to adjust the irradiation angle. In a practical application scenario, the telescopic state of the first telescopic arm 212 and the second telescopic arm 213 can be adjusted by automatically/manually adjusting the rotation fixing portion 214, so that the irradiation range of the lamp set is simply extended in the telescopic direction of the first telescopic arm 212 and the second telescopic arm 213.

The intelligent control unit is arranged on at least one of the base 1, the supporting unit and the phototrophic unit 2. Preferably, the intelligent control unit comprises a control console 3 arranged in the middle of the supporting unit, and the control console 3 is respectively connected with a telescopic supporting rod 4 below and a connecting component above. As the function interface expansion part, the intelligent control unit may be an intelligent control unit including a single-chip microcomputer, and specifically, the intelligent control unit may include five parts: (1) The central processing unit is composed of a singlechip and is used for processing signals and sending control commands, and the singlechip can be STC89C52RC, STM32, 89S52 singlechips and the like; (2) A display unit, for example, a liquid crystal display, is used for displaying various parameters and data, such as brightness, height, color temperature, indoor temperature and humidity, time and the like; (3) The control module is used for controlling the adjustment parameters and controlling the lamp groups of the light nutrition unit 2 to be switched between different illumination modes; such as being switchable between a work mode, a rest mode, an outdoor lighting mode, a daily lighting mode. (4) The sensor part may include, for example, an illuminance sensor such as a TSL2561 chip, a temperature and humidity sensor such as a DS18B20 chip, a photoresistor, an ultrasonic ranging sensor such as HC-SR04, a human body infrared sensor such as a BISS0001 chip, etc., for collecting the above various parameters and data and detecting the distance of the phototrophic unit 2 from the human body; in addition, a sound sensor or other types of sensors such as a sensor for monitoring color temperature, color rendering index and peak wavelength can be arranged according to the requirement, and the monitoring result is sent to a receiving module of the control unit for monitoring and controlling different parameters; (5) And a circuit connection part which connects the central processing unit, the display unit, the sensor, the phototrophic unit 2, the clock circuit, and the like through a connection unit such as a wire or the like.

Since the biological clock and the circadian rhythm in the human body are affected by light, light rays secrete melatonin through controlling the pine cone body, thereby affecting the circadian rhythm of the human body. Therefore, the control unit in the intelligent console 3 can perform mode switching by adjusting illuminance and the like, so that the intelligent console is applicable to different scenes; preferably, the device of the utility model can be further provided with one or more interfaces on at least one of the base 1, the supporting unit, the phototrophic unit 2 and the console 3, and the interfaces are used for installing other power utilization modules such as common lamps and lanterns, and are used as common lamp holders, thereby playing a multifunctional role of the phototrophic lamps and the common lighting lamps. Taking a common lamp and other lighting equipment as an example, the common lamp can be electrically connected through a flexible supporting arm and controlled by a lighting module of a control unit, so that the lighting module can provide an illuminance range below 500lux, and the universality and compatibility of the phototrophic device are further realized. At least the following phototrophic modes can be provided:

(1) Myopia prevention and control mode (simulated outdoor): the full spectrum of 10-20% of purple light is added on the basis of the original purple light content, and the illumination intensity at the center of an illumination plane is 800-2500lux, preferably 1000-2000;

(2) Skin light maintenance/cosmetic mode: the mixed light with the wavelength of 550-695nm irradiates 1000-3500lux in the center of the plane;

(3) Pattern of hair loss prevention: red light with the wavelength of 650-680nm and the illumination intensity at the center of an illumination plane of 1000-3500lux;

(4) Mode of nourishing therapy: the full spectrum is irradiated with the central illumination of 2000-15000lux.

A general illumination pattern may also be provided, including:

(1) In rest mode, the illumination device is only turned on, and the illuminance can be adjusted between 0 and 100 lux. Under the illumination condition, the melatonin secretion level is improved, which is helpful for relieving emotion and promoting physiological function restoration.

(2) The daily lighting mode is to switch on only the lighting device, and the illuminance is adjusted between 100 and 500 lux. The illumination condition is similar to general illumination conditions, such as a desk lamp, a common indoor lamp and the like, and can meet the daily illumination requirement.

The user can adjust the illuminance through the mobile phone APP remote control, or through remote control illuminance, or through control panel button control illuminance.

The base 1 is used for fixing the phototrophic apparatus on a plane. The base 1 can be in a shape of a circular, square or rectangular flat disc, is provided with a lithium battery, is correspondingly provided with a charging interface and a normal external electric wire, so that the phototrophic device can be used in a wired or wireless mode.

In order to facilitate the movement, a roller may be provided at the lowermost portion of the base 1. The rollers can be directional rollers or universal wheels, or can be used in combination, for example, a group of directional wheels are arranged on the left side and the right side of the base 1, and a group of universal wheels are arranged on the front side and the rear side of the base 1. Each group of the orientation wheels can be a plurality of wheels which are matched with each other, such as one orientation wheel on the left and the right, or two orientation wheels on the left and the right, of course, the utility model is not limited to this, as long as the gravity center balance can be ensured. In a similar manner, each set of universal wheels may be a plurality of wheels that cooperate with one another, such as a front-to-back one directional wheel, or a left-to-right two directional wheel, or a front-to-back two. The directional wheel or the universal wheel can be further provided with a locking mechanism, the locking mechanism can be an elastic piece or other similar structures, one end of the locking mechanism can be fixed on the base 1, the other end of the locking mechanism can rotate towards the wheel hub relative to the fixed end, and when the base 1 does not need to move, the wheel can be locked by only pulling down the elastic piece and propping one end of the elastic piece against the wheel hub. The direction of movement can be adjusted without any effort by using the directional wheel and the universal wheel in combination. On the basis, a mobile control module is built in the base 1, so that the roller is in signal connection with the control unit and moves to a set position according to a control instruction.

In addition, an intelligent robot can be installed on the base 1, and the intelligent robot can move to different rooms according to AI control to perform timing, quantitative and fixed-point irradiation on different crowds, for example, the intelligent robot can automatically move to a bookend at a first preset time point, so that a user can select to irradiate children in a myopia prevention mode, can automatically move to the side of a living room television at a second preset time point, so that the user can select to irradiate old people in a calcium supplementing mode, can automatically move to a bedroom at a third preset time point, so that the user can select to irradiate females in a beautifying mode, and the like.

The support unit is detachably connected with the base 1 and the phototrophic unit 2; or the supporting unit can be divided into a telescopic supporting rod 4 below and a connecting component above through a console 3 positioned in the middle of the supporting unit; the telescopic supporting rod 4 is detachably connected to the base 1, and the connecting component is connected with the phototrophic unit 2 and drives the phototrophic unit 2 to move and position in a three-dimensional space. The supporting unit can comprise a supporting rod made of PC/PVC/PMMA plastic or metal. The supporting rod can be set to be of a telescopic structure, for example, two nested hollow rods with different diameters are respectively provided with a clamp spring and a buckle/clamping groove, the thin rod can be inserted into the thick rod, and the telescopic length is adjusted through the clamp spring and the buckle/clamping groove, so that the height and the length can be adjusted, and the phototrophic unit 2 is suitable for different crowds or different scenes.

The connecting assembly comprises a first rotating arm 5 and a second rotating arm 6 so as to drive the phototrophic unit 2 to move and position in a three-dimensional space. Specifically, one end of the second rotating arm 6 is rotatably connected to the connection portion 21 of the phototrophic unit 2, so that the phototrophic unit 2 is rotatably mounted on the second rotating arm 6, and the other end is connected to one end of the first rotating arm 5. One end of the first rotating arm 5 is rotatably mounted on the console 3, the other end is connected to one end of the second rotating arm 6, and the second rotating arm 6 takes the first rotating arm 5 as a rotating shaft. Through the arrangement, the phototrophic unit 2 has the irradiation range of the whole space, and the base 1 flexibly moves, so that the phototrophic device can meet the illumination requirements of the whole space at different positions.

The foregoing description of the preferred embodiments of the present utility model has been presented for purposes of clarity and understanding, and is not intended to limit the utility model to the particular embodiments disclosed, but is intended to cover all modifications, alternatives, and improvements within the spirit and scope of the utility model as outlined by the appended claims.

Claims (10)

1. An intelligent phototrophic device is characterized by comprising a base, a supporting unit, an intelligent control unit and a phototrophic unit;

the top of the base is connected with a supporting unit, and the top of the supporting unit supports the phototrophic unit;

a phototrophic unit comprising a plurality of lamp groups, wherein the lamp groups enable the illumination intensity of an illumination area to be adjusted within 800-30000 lux;

the intelligent control unit is arranged on at least one of the base, the supporting unit and the phototrophic unit;

the intelligent control unit comprises a plurality of light control modules for controlling the lamp groups of the light nutrition unit to switch between different illumination modes.

2. The intelligent light nutrition apparatus of claim 1, wherein the base comprises a battery and a charging interface thereof, the battery being electrically connected to the control unit.

3. The intelligent phototrophic apparatus of claim 2, wherein the bottom of the base is provided with a roller in signal connection with the intelligent control unit, the roller being a directional wheelset, a universal wheelset, or a combination thereof.

4. A smart phototrophic apparatus according to any one of claims 1 to 3, wherein the support unit comprises a lower telescopic support rod and an upper connecting assembly; the telescopic supporting rod is detachably connected to the base, and the connecting component is connected with the phototrophic unit and drives the phototrophic unit to move and position in a three-dimensional space.

5. The intelligent phototrophic apparatus of claim 4, wherein the light bank of phototrophic units is composed of a plurality of detachable light bank modules, each light bank module comprises a plurality of light sources, and the light sources are LED lamps, laser lamps or a combination thereof.

6. The intelligent phototrophic apparatus of claim 5, wherein the intelligent control unit includes a console disposed in a middle portion of the support unit, the console being connected to the lower telescopic support rod and the upper connecting assembly, respectively.

7. The intelligent phototrophic apparatus of claim 6, wherein the connection assembly includes a first swivel arm rotatably mounted at the console at one end and a second swivel arm rotatably connected at the other end of the first swivel arm, the phototrophic unit rotatably mounted at an end of the second swivel arm remote from the first swivel arm.

8. The intelligent phototrophic apparatus of claim 7, wherein the phototrophic unit includes a connection portion rotatably coupled to an end of the second rotary arm remote from the first rotary arm, and a mounting portion rotatably secured to the connection portion, the mounting portion securing the lamp set.

9. The intelligent phototrophic apparatus of any of claims 5 to 8, further comprising an illumination sensor for monitoring at least one optical parameter of the illumination zone and for transmitting the monitoring result to a receiving module of the intelligent control unit.

10. The apparatus of claim 9, further comprising a lighting device electrically connected to at least one of the base, the support unit, and the phototrophic unit via a flexible support arm and controlled by the lighting module of the intelligent control unit.

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