CN112840887A - Light supplementing method for crop phytotron - Google Patents

Light supplementing method for crop phytotron Download PDF

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CN112840887A
CN112840887A CN202110013562.XA CN202110013562A CN112840887A CN 112840887 A CN112840887 A CN 112840887A CN 202110013562 A CN202110013562 A CN 202110013562A CN 112840887 A CN112840887 A CN 112840887A
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杜士云
李泽福
刘银燕
王辉
王玉
马廷臣
王伍梅
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Anhui Xrf Technology Co ltd
Rice Research Institute of Guangdong Academy of Agricultural Sciences
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    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
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    • AHUMAN NECESSITIES
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    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
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Abstract

The present disclosure provides a light supplement method for a crop phytotron, which includes: establishing an energy equation of a crop artificial climate chamber, and adjusting illumination irradiated into the crop artificial climate chamber according to the energy equation so that the illuminated photosynthesis spectral energy of a crop bed inside the crop artificial climate chamber is the same as the illuminated photosynthesis spectral energy of an outdoor crop bed, and the inside of the crop artificial climate chamber is within a preset temperature; wherein, the energy equation of the crop artificial climate chamber in unit time is as follows:
Figure DDA0002885871270000011
Figure DDA0002885871270000012

Description

农作物人工气候室的补光方法The supplementary light method for the artificial climate chamber of crops

技术领域technical field

本公开涉及一种农作物人工气候室的补光方法,属于农作物人工栽培技术领域。The disclosure relates to a method for supplementing light in an artificial climate chamber for crops, belonging to the technical field of artificial cultivation of crops.

背景技术Background technique

近年来,极度天气频发,其中高温热害对水稻生产造成严重影响,因此,鉴定水稻耐热性的农作物人工气候室是水稻选育种的必要设施之一。In recent years, extreme weather has occurred frequently, and high temperature heat damage has seriously affected rice production. Therefore, an artificial climate chamber for identifying heat resistance of rice is one of the necessary facilities for rice breeding.

不同水稻品种对高温敏感性不同,耐热和不耐热品种之间花器官及生理特性差异显著;筛选鉴定耐热性水稻品种,对保障粮食安全具有重要意义;因此迫切需要建设满足水稻耐热性鉴定需求的水稻人工栽培实验室,即建设水稻耐热性鉴定农作物人工气候室。Different rice varieties have different sensitivity to high temperature, and there are significant differences in floral organs and physiological characteristics between heat-resistant and heat-labile varieties. Screening and identification of heat-tolerant rice varieties is of great significance to ensure food security; therefore, it is urgent to construct rice plants that meet the needs of heat resistance. The artificial cultivation laboratory of rice for the needs of sex identification, that is, the construction of an artificial climate room for rice heat resistance identification crops.

水稻耐热性鉴定农作物人工气候室一般是玻璃实验房,玻璃实验房要模拟自然高温恶劣条件,对光照、温度、湿度、通风都有很严格要求,需要安装制冷/热泵设备、空气循环系统对玻璃实验房内的热量进行调节,控制合适的温度和湿度;太阳辐射是玻璃实验房的主要而又不稳定的热源,对制冷/热泵的热负荷大小和室内温度调控精度影响很大,并直接影响作物的生长、开花、结实;农作物人工气候室的温度调控需要消耗能量,特别是在日晒的玻璃房实验室内的温度调控,需要热分析的理论指导,还要考虑节能等实际情况。The artificial climate room for rice heat resistance identification is generally a glass laboratory room. The glass laboratory room must simulate the harsh conditions of natural high temperature and have strict requirements on light, temperature, humidity and ventilation. It needs to install refrigeration/heat pump equipment and air circulation system. The heat in the glass laboratory room is adjusted to control the appropriate temperature and humidity; solar radiation is the main and unstable heat source of the glass laboratory room, which has a great impact on the heat load of the refrigeration/heat pump and the indoor temperature regulation accuracy, and directly It affects the growth, flowering and fruiting of crops; the temperature regulation of the artificial climate chamber of crops requires energy consumption, especially the temperature regulation in the sun-dried glass room laboratory, which requires theoretical guidance of thermal analysis, and also considers practical conditions such as energy saving.

目前,农作物人工气候室的光、热分析缺乏理论指导,农作物人工气候室能量分析应当包括热平衡分析和光合作用平衡分析,但是目前欠缺兼顾光、热两方面分析文章;其原因也许是农科院农作物栽培人员缺乏热物理领域知识,而热物理领域技术人员也不了解农作物人工气候室的状况;热工技术人员仅仅采用房间空调的能量平衡分析方法,是不能正确分析农作物人工气候室的能量平衡情况。At present, the light and heat analysis of the crop artificial climate chamber lacks theoretical guidance. The energy analysis of the crop artificial climate chamber should include heat balance analysis and photosynthesis balance analysis, but there is currently a lack of analysis articles that take into account both light and heat; the reason may be that the Academy of Agricultural Sciences Crop cultivators lack the knowledge in the field of thermophysics, and technicians in the field of thermophysics do not understand the condition of the artificial climate chamber of crops; thermal technicians only use the energy balance analysis method of room air conditioners, and they cannot correctly analyze the energy balance of the artificial climate chamber of crops Happening.

对于太阳辐射影响农作物人工气候室热负荷的节能调控手段之一是采用遮阳措施,在阳光强烈的时候用遮光网减少太阳入射面积,这措施节能是有效的;但是,遮光后作物的光合作用能量减少,会影响作物的开花结实;有遮光的热分析如何进行,怎样设计遮光系统怎样设计,遮光度是多少合理,缺乏理论分析指导。One of the energy-saving regulation methods for the effect of solar radiation on the heat load of the artificial climate chamber of crops is to use shading measures. When the sun is strong, use shading nets to reduce the area of solar incidence. This measure is effective for energy saving; however, the photosynthetic energy of crops after shading The reduction will affect the flowering and fruiting of crops; how to conduct thermal analysis with shading, how to design the shading system, how much is reasonable shading degree, lack of theoretical analysis guidance.

近来,对于人工光源代替自然光源,促进作为生长,进行了许多研究,有文献介绍其中波长在620nm-750nm的红光,叶绿素能吸收75%-85%,该波段波长的红光对植物(种子)发芽,开花,结果,植物体叶绿素的合成,光和作用等有促进作用;波长在420nm--500nm的蓝紫光,叶绿素能吸收90%以上,是植物生长和光合作用很强的一个波段,它能促进作物根块发育、生长点降低,叶茎变粗;使作物强壮,抗病能力明显增强;而产生这些光谱的新型灯源是LED灯源。Recently, many studies have been carried out on artificial light sources instead of natural light sources to promote growth. Some literatures introduce red light with a wavelength of 620nm-750nm, and chlorophyll can absorb 75%-85%. ) germination, flowering, fruiting, the synthesis of plant chlorophyll, and the effect of light and other functions are promoted; the blue-violet light with a wavelength of 420nm--500nm, chlorophyll can absorb more than 90%, which is a strong band for plant growth and photosynthesis. It can promote the development of crop roots, reduce the growth point, and thicken the leaves and stems; make the crops stronger and significantly enhance the disease resistance; and the new light source that produces these spectrums is the LED light source.

LED灯的光源可作为水稻耐热性鉴定农作物人工气候室的补充光源。但是,目前自然光调节和补偿光调控都停留在经验基础上,没有系统的理论计算;缺乏自然光调节和补偿光的量化关系指导,难以实现自然光调节和补偿光智能节能匹配控制,也给农作物的农作物人工气候室的温度、湿度精准控制带来难度。The light source of the LED lamp can be used as a supplementary light source for the artificial climate chamber of rice heat resistance identification crops. However, at present, both natural light regulation and compensation light regulation are based on experience, and there is no systematic theoretical calculation; lack of guidance on the quantitative relationship between natural light regulation and compensation light, it is difficult to achieve intelligent energy-saving matching control of natural light regulation and compensation light. The precise control of temperature and humidity in the artificial climate chamber brings difficulties.

发明内容SUMMARY OF THE INVENTION

为了解决上述技术问题之一,本公开提供了一种农作物人工气候室的补光方法。In order to solve one of the above technical problems, the present disclosure provides a method for supplementing light in an artificial climate chamber for crops.

根据本公开的一个方面,提供了一种农作物人工气候室的补光方法,其包括:According to one aspect of the present disclosure, there is provided a method for supplementing light in an artificial climate chamber for crops, comprising:

建立农作物人工气候室的能量方程,Establish the energy equation of the artificial climate chamber for crops,

根据所述能量方程,调节照射入农作物人工气候室的光照,使得农作物人工气候室内部的农作物床的受照光合作用光谱能量与室外的农作物床的受照光合作用光谱能量相同,并使得所述农作物人工气候室内部处于预设温度内;According to the energy equation, the light irradiated into the crop artificial climate chamber is adjusted so that the photosynthetic spectral energy of the crop bed inside the crop artificial climate chamber is the same as the photosynthetic spectral energy of the outdoor crop bed, and the said The interior of the crop artificial climate chamber is within the preset temperature;

其中,所述的农作物人工气候室的单位时间能量方程为:Wherein, the unit time energy equation of the crop artificial climate chamber is:

Figure BDA0002885871250000021
Figure BDA0002885871250000021

所述能量方程中,正号为能量输入,负号为能量消耗,单位均为W;Q1为输入到农作物人工气候室内的太阳能量;Q2为补偿光灯消耗的电能量;Q3为农作物人工气候室内气流均匀化的附加风机消耗的电能量;Q4为玻璃罩对室内的传热量;Qp1、Qp2为农作物床吸收的太阳光和补偿光中的光合作用能量;Qρ是作物床反射到室外的辐射能量;

Figure BDA0002885871250000022
为空调机循环风送给农作物人工气候室冷量或热量,当输入热量时为正号,输入冷量时为负号;±Qm为农作物人工气候室内的室内空气热容、作物床植株热容和根系土壤的热容吸热或放热量,吸热为负号,放热为正号。In the described energy equation, the positive sign is the energy input, the negative sign is the energy consumption, and the unit is W; Q 1 is the solar energy input into the artificial climate room for crops; Q 2 is the electric energy consumed by the compensation light; Q 3 is The electric energy consumed by the additional fan for uniform air flow in the artificial climate of crops; Q 4 is the heat transfer from the glass cover to the room; Q p1 and Q p2 are the sunlight absorbed by the crop bed and the photosynthetic energy in the compensation light; Q ρ is radiant energy reflected from the crop bed outdoors;
Figure BDA0002885871250000022
The circulating air of the air conditioner sends the cooling or heat to the artificial climate room for crops. When the heat input is positive, it is negative when the cooling is input; ±Q m is the indoor air heat capacity in the artificial climate room for the crops, and the heat of the crop bed plants. The heat capacity of the root soil is endothermic or exothermic, the endothermic is negative, and the exothermic is positive.

根据本公开一个实施方式所述的农作物人工气候室的补光方法,当所述农作物人工气候室在未被遮挡时:According to the method for supplementing light in an artificial climate room for crops according to an embodiment of the present disclosure, when the artificial climate room for crops is not blocked:

Q1=Gin,θA0=Gout,θτA0=(Gbcosθ+Gd)τA0 Q 1 =G in, θ A 0 =G out, θ τA 0 =(G b cosθ+G d )τA 0

其中,Gin,θ和Gout,θ分别为农作物人工气候室内部和外部的水平面受到太阳辐照强度,单位为W/m2,θ表示太阳光线的天顶角;τ为玻璃的平均透光率;A0为农作物人工气候室农作物床的面积,单位为m2;Gb为直射太阳辐射强度;Gd为散射太阳辐射强度;取Gb/Gd=6/4。Among them, G in, θ and G out, θ are the solar radiation intensity on the horizontal plane inside and outside the crop artificial climate chamber respectively, the unit is W/m 2 , θ is the zenith angle of sunlight; τ is the average transmittance of the glass light rate; A 0 is the area of the crop bed in the artificial climate chamber of crops, in m 2 ; G b is the direct solar radiation intensity; G d is the scattered solar radiation intensity; take G b /G d =6/4.

根据本公开一个实施方式所述的农作物人工气候室的补光方法,当所述农作物人工气候室使用顶棚遮光网时:Q1记为Q1,πAccording to the method for supplementing light in an artificial climate room for crops according to an embodiment of the present disclosure, when the artificial climate room for crops uses a ceiling shading net: Q 1 is denoted as Q 1, π ,

Q1,π=[Gout,θ,b(1-πb)+Gd(1-πF21)]τA0 (4)Q 1, π = [G out, θ, b (1-π b )+G d (1-πF 21 )]τA 0 (4)

其中,Gout,θ,b为无遮光时太阳入射角为θ的太阳直射辐射能;πb为遮光网减少的直射辐射能的份额,等于作物床被遮光网遮挡的直射太阳照射面积份额与遮光网的遮光度π的乘积;当遮光网顶棚与作物床平行高度为Z,作物床宽度为xb,遮光网宽度为xz,从遮光网顶棚左端射到作物床的右端光线La的天顶角为θa,从遮光网顶棚左端射到作物床的左端光线Lb的天顶角为θb时;Among them, G out, θ, b is the direct solar radiant energy with the sun incident angle θ when there is no shading; π b is the share of the direct radiant energy reduced by the shading net, which is equal to the proportion of the direct sunlight irradiated area of the crop bed blocked by the shading net and the The product of the shading degree π of the shading net; when the parallel height of the shading net roof and the crop bed is Z, the width of the crop bed is x b , and the width of the shading net is x z , from the left end of the shading net roof to the right end of the crop bed The light La When the zenith angle is θ a , when the zenith angle of the light L b from the left end of the shading net roof to the left end of the crop bed is θ b ;

当θ≥θa时没有作用,There is no effect when θ≥θ a ,

πb=0 (θ≥θa) (5a)π b = 0 (θ≥θ a ) (5a)

当θ<θa以后,随θ的继续减小,在作物床上出现遮光网的阴影面积,天顶角为θ的光线La在作物床上产生的阴影宽度用xπ表示,When θ < θ a , as θ continues to decrease, the shadow area of the shading net appears on the crop bed, and the width of the shadow produced by the light La with a zenith angle of θ on the crop bed is represented by x π ,

xπ=Z tanθa-Z tanθ=xa-xθ x π =Z tanθ a -Z tanθ = x a -x θ

xa=Z tanθa,xθ=Z tanθ,xb=Z tanθbx a = Z tan θ a , x θ = Z tan θ , x b = Z tan θ b ;

Figure BDA0002885871250000031
Figure BDA0002885871250000031

当θb>θ后When θ b > θ

πb=π (5c)π b = π (5c)

式(4)的散射辐射能Gd(1-πF21)中的πF21为遮光网在半球空间辐射中占有的份额,F21视觉系数为作物床平面所拦截的从遮光网顶棚面来的辐射份额;The πF 21 in the scattered radiation energy G d (1-πF 21 ) of the formula (4) is the share of the shading net in the hemispherical space radiation, and the F 21 visual coefficient is the intercepted by the crop bed plane from the shading net ceiling surface. radiation share;

根据太阳高度不同,天顶角θ不同,选择式(5a)或(5b)或(5c)代入式(4),计算有遮光时进入农作物人工气候室的太阳辐射能Q1,πAccording to the different height of the sun and the different zenith angle θ, choose formula (5a) or (5b) or (5c) and substitute it into formula (4) to calculate the solar radiation energy Q 1, π that enters the artificial climate chamber of crops when there is shading;

当θ=0时,When θ=0,

Q1,π,θ=0=[Gout,θ,b(1-π)+Gd(1-πF21)]τA0 (θ=0) (4a)。Q 1 , π, θ=0 = [G out, θ, b (1−π)+G d (1−πF 21 )]τA 0 (θ=0) (4a).

根据本公开一个实施方式所述的农作物人工气候室的补光方法,当采用铺设于农作物人工气候室顶层玻璃上面的红外反射半透明膜时,Q1记为Q1,πp,可见光的遮光度为πp=0.1,可见光能量在太阳全辐射能中所占的份额为

Figure BDA0002885871250000047
红外辐射反射膜的对波长λ≥780nm的红外光辐射遮光度为πh=0.9,波长λ≥780nm的红外光辐射能在太阳全辐射能中所占的份额为
Figure BDA0002885871250000048
According to the method for supplementing light in an artificial climate chamber for crops according to an embodiment of the present disclosure, when the infrared reflective translucent film laid on the top glass of the artificial climate chamber for crops is used, Q 1 is recorded as Q 1, πp , the shading degree of visible light is π p = 0.1, the share of visible light energy in the total solar radiation energy is
Figure BDA0002885871250000047
The shading degree of infrared radiation reflection film to infrared light radiation with wavelength λ≥780nm is π h = 0.9, and the share of infrared light radiation energy with wavelength λ≥780nm in the total solar radiation energy is
Figure BDA0002885871250000048

当采用顶层红外反射半透明膜时,太阳直射辐射能和散射辐射能分解为可见光和红外辐射两部分能量,并分别使用不同的遮光率πp和πh,使用红外反射半透明膜时,进入作物人工实验室的太阳辐射能为:When the top infrared reflective translucent film is used, the direct solar radiation energy and scattered radiant energy are decomposed into visible light and infrared radiation, and different shading rates π p and π h are used respectively. When the infrared reflective translucent film is used, entering The solar radiation energy of the crop artificial laboratory is:

Figure BDA0002885871250000041
Figure BDA0002885871250000041

式(6)按可见光部和红外辐射整理,得:Formula (6) is arranged according to the visible light part and the infrared radiation, we get:

Figure BDA0002885871250000042
Figure BDA0002885871250000042

当正午θ=0时,cosθ=1,记πb,p=πp,πb,h=πh,所以式(7)化作(7a)或(7b):When θ=0 at noon, cosθ=1, denote π b, p = π p , π b, h = π h , so formula (7) becomes (7a) or (7b):

Figure BDA0002885871250000043
Figure BDA0002885871250000043

Figure BDA0002885871250000049
Figure BDA0002885871250000049

其中,可见光的入室能量为:Among them, the entering energy of visible light is:

Figure BDA0002885871250000044
Figure BDA0002885871250000044

太阳红外辐射的入室能量为:The incoming energy of solar infrared radiation is:

Figure BDA0002885871250000045
Figure BDA0002885871250000045

与无遮光方案相比,入室的太阳能量差值为:Compared with the no-shading scheme, the difference in solar energy entering the room is:

Figure BDA0002885871250000046
Figure BDA0002885871250000046

式(9)中,可见光减少量为:In formula (9), the amount of visible light reduction is:

Figure BDA0002885871250000051
Figure BDA0002885871250000051

远红外辐射能减少量:Far-infrared radiant energy reduction:

Figure BDA0002885871250000052
Figure BDA0002885871250000052

与遮光网方案相比,入室的太阳辐射能量差值为:Compared with the shading net scheme, the difference in solar radiation energy entering the room is:

Figure BDA0002885871250000053
Figure BDA0002885871250000053

遮光网方案的可见光偏少量为:The visible light partial amount of the shading net scheme is:

Figure BDA0002885871250000054
Figure BDA0002885871250000054

扣除绿光份额后,遮光网方案的作物光合作用辐射能偏少量为:After deducting the green light share, the partial amount of crop photosynthesis radiant energy in the shading net scheme is:

Figure BDA0002885871250000055
Figure BDA0002885871250000055

减少补光灯的电功率为:To reduce the electric power of the fill light is:

ΔP2,π-ρ=ΔQπ,VLd (16)ΔP 2, π-ρ = ΔQ π, VLd (16)

但是远红外辐射能增加量:But far-infrared radiant energy increases by:

Figure BDA0002885871250000056
Figure BDA0002885871250000056

绿光辐射能比遮光网的增多量为:The increase of green radiant energy than the shading net is:

Figure BDA0002885871250000057
Figure BDA0002885871250000057

按空调机性能系数COP计算,红外反射遮光膜的方案比遮光网的方案节省电功率为:Calculated according to the COP of the performance coefficient of the air conditioner, the scheme of infrared reflective shading film saves electric power compared with the scheme of shading net as follows:

ΔP2,π-p=ΔP2,π-ρ-(ΔQπ,IR-ΔQπ,ρ)/COP (19)。ΔP 2,π−p =ΔP 2,π− ρ−(ΔQπ ,IR −ΔQπ )/COP (19).

根据本公开一个实施方式所述的农作物人工气候室的补光方法,农作物床的作物从太阳光吸收的光合作用的能量Qp1为:According to the method for supplementing light in an artificial climate chamber for crops according to an embodiment of the present disclosure, the photosynthetic energy Q p1 absorbed by the crops in the crop bed from sunlight is:

Figure BDA0002885871250000058
Figure BDA0002885871250000058

其中,记

Figure BDA0002885871250000059
为太阳光中可被植物吸收的光合作用的能量份额,αp为植物的对光合作用光谱辐射能的吸收率,ξ为光合作用从光能变成化学能的效率;Among them, note
Figure BDA0002885871250000059
is the energy share of photosynthesis that can be absorbed by plants in sunlight, α p is the absorption rate of photosynthesis spectral radiant energy by plants, and ξ is the efficiency of photosynthesis from light energy to chemical energy;

在正午,无遮光时:At noon, without shade:

Figure BDA00028858712500000510
Figure BDA00028858712500000510

在使用遮光网时:When using shade nets:

Figure BDA00028858712500000511
Figure BDA00028858712500000511

在使用红外反射遮光膜时:When using IR reflective shading film:

Figure BDA00028858712500000512
Figure BDA00028858712500000512

根据本公开一个实施方式所述的农作物人工气候室的补光方法,能量方程的补偿光中的光合作用光谱能量Qp2为室外、内的可见光光谱段的能量差,在无遮光时:According to the method for supplementing light in an artificial climate chamber for crops according to an embodiment of the present disclosure, the photosynthesis spectral energy Q p2 in the compensation light of the energy equation is the energy difference between the outdoor and indoor visible light spectral bands, and when there is no shading:

Figure BDA0002885871250000061
Figure BDA0002885871250000061

补光灯的功率为:The power of the fill light is:

Figure BDA0002885871250000062
Figure BDA0002885871250000062

其中,ηd为补偿光灯的电光转化效率;Wherein, η d is the electro-optical conversion efficiency of the compensation light lamp;

在无遮光且正午θ=0时的补偿光灯的能量Q2,θ=0、被作物吸收的光合作用能量记作Qp2,θ=0When there is no shading and θ=0 at noon, the energy Q 2 of the compensation light, θ=0 , the photosynthetic energy absorbed by the crop is recorded as Q p2, θ=0 ;

Figure BDA0002885871250000063
Figure BDA0002885871250000063

Figure BDA0002885871250000064
Figure BDA0002885871250000064

在采用顶棚遮光网θ=0时,Q1采用式(4)的Q1,π计算,Q2记作Q2,π,Qp2记作Qp2,π,则:When using the ceiling shading net θ=0, Q1 is calculated using Q 1, π of formula (4), Q 2 is denoted as Q 2, π , and Q p2 is denoted as Q p2, π , then:

Figure BDA0002885871250000065
Figure BDA0002885871250000065

Figure BDA0002885871250000066
Figure BDA0002885871250000066

在采用红外反射遮光膜时,且正午时的补偿光功率

Figure BDA0002885871250000067
和被农作物吸收的能量
Figure BDA0002885871250000068
When using infrared reflective shading film, and the compensation optical power at noon
Figure BDA0002885871250000067
and energy absorbed by crops
Figure BDA0002885871250000068

Figure BDA0002885871250000069
Figure BDA0002885871250000069

Figure BDA00028858712500000610
Figure BDA00028858712500000610

其中,Qout,0取100。Among them, Q out, 0 is 100.

根据本公开一个实施方式所述的农作物人工气候室的补光方法,农作物人工气候室反射的辐射能Qρ为:According to the method for supplementing light in an artificial climate room for crops according to an embodiment of the present disclosure, the radiant energy Q ρ reflected by the artificial climate room for crops is:

Figure BDA00028858712500000611
Figure BDA00028858712500000611

其中,

Figure BDA00028858712500000612
in,
Figure BDA00028858712500000612

当无遮光θ=0时的绿光反射量,记作Qρ,θ=0When there is no shading θ=0, the green light reflection amount is denoted as Q ρ, θ=0 ;

Figure BDA00028858712500000613
Figure BDA00028858712500000613

当顶层采用遮光网遮光且θ=0,遮光网的遮光度π=0.6时的绿光反射量,记作Qρ,θ=0,π=0.6When the top layer adopts a shading net to shield the light and θ=0, the green light reflection amount when the shading degree of the shading net is π=0.6 is recorded as Q ρ, θ=0, π=0.6 ;

Figure BDA00028858712500000614
Figure BDA00028858712500000614

当采用红外反射遮光膜时,可见光遮光度为πp=0.1,红外遮光度为πp,h,θ=0时的绿光反射量,记作Qρ,θ=0,π=0.1When the infrared reflective shading film is used, the visible light shading degree is π p = 0.1, the infrared shading degree is π p, h , the green light reflection amount when θ = 0 is denoted as Q ρ, θ = 0, π = 0.1 ,

Figure BDA0002885871250000071
Figure BDA0002885871250000071

其中at取0.6,ad取0.4,Gout=Gb+Gdwhere at is 0.6, a d is 0.4, and G out =G b +G d .

根据本公开一个实施方式所述的农作物人工气候室的补光方法,所述能量方程中的Q4为玻璃罩对室内的传热量:According to the method for supplementing light in an artificial climate room for crops according to an embodiment of the present disclosure, Q4 in the energy equation is the heat transfer amount of the glass cover to the room:

在白天:In the daytime:

Q4=0.5Gout(1-τ-ρ)A0=0.5(Gbcosθ+Gd)αA0 (26)Q 4 =0.5G out (1-τ-ρ)A 0 =0.5(G b cosθ+G d )αA 0 (26)

当正午太阳天顶角θ=0°时,When the noon sun zenith angle θ=0°,

Q4=0.5(Gb+Gd)(1-τ)A0=0.5Gout(1-τ-ρ)A0 (26a)Q 4 =0.5(G b +G d )(1-τ)A 0 =0.5G out (1-τ-ρ)A 0 (26a)

夜晚没有太阳辐射,则There is no solar radiation at night, then

Q4=KA(Tg1-T)=KA(Tout-Tg2) (27)Q 4 =KA(T g1 -T)=KA(T out -T g2 ) (27)

式中K为玻璃壁对空气的平均传热系数,A为玻璃房的玻璃壁面积,Tg1、Tg2分别为室内、外侧玻璃温度,T、Tout分别为室内、外空气温度。In the formula, K is the average heat transfer coefficient of the glass wall to the air, A is the glass wall area of the glass room, T g1 and T g2 are the indoor and outer glass temperatures, respectively, and T and T out are the indoor and outdoor air temperatures, respectively.

根据本公开一个实施方式所述的农作物人工气候室的补光方法,农作物人工气候室的热容吸热或放热量QmAccording to the method for supplementing light in an artificial climate room for crops according to an embodiment of the present disclosure, the heat capacity of the artificial climate room for crops absorbs heat or releases heat Q m :

Qm=MacadTa/dt+MfcfdTf/dt+MscsdTs/dt (28)Q m =M a c a dT a /dt+M f c f dT f /dt+M s c s dT s /dt (28)

式中的Ma、Mf、Ms分别为农作物人工气候室内的空气、作物床秸秆、作物床的植物根系土壤的质量,Ma≈Mf<<Ms,所以Mscs的热容是农作物人工气候室的热沉,其温度变化不敏感,当植物根系土壤温度达到设定值后,温度控制只要保留空气和作物床植株的热容波动项;dTa/dt、dTf/dt、dTs/dt分别为室内空气平均气温、作物床秸秆平均温度、作物床的植物根系土壤平均温度的变化速率;In the formula , Ma , M f , and Ms s are the quality of the air, crop bed straw , and plant root soil of the crop bed, respectively . The capacity is the heat sink of the artificial climate chamber of crops, and its temperature change is not sensitive. When the soil temperature of the plant root reaches the set value, the temperature control only needs to keep the heat capacity fluctuation terms of the air and the crop bed plants; dT a /dt, dT f / dt and dT s /dt are the rate of change of the average indoor air temperature, the average temperature of the crop bed straw, and the average temperature of the plant root soil in the crop bed;

当农作物人工气候室的室内空气温度控制要求30分钟内允许波动1℃,植株和空气的热容基本相同,Qm通过下式获得:When the indoor air temperature control of the artificial climate room for crops requires a fluctuation of 1°C within 30 minutes, the heat capacity of the plant and the air is basically the same, and Q m is obtained by the following formula:

Qm=(Mafcaf)dTa/dt (29)Q m =(M af c af )dT a /dt (29)

其中Mafcaf=Maca+Mfcfwhere M af c af = M a c a + M f c f .

根据本公开一个实施方式所述的农作物人工气候室的补光方法,空调机循环风送给农作物人工气候室冷量或冷量±QkAccording to the method for supplementing light in an artificial climate room for crops according to an embodiment of the present disclosure, the circulating air of the air conditioner is sent to the artificial climate room for crops with cooling capacity or cooling capacity ±Q k :

±Qk=maca(th-tc)=Q1+Q2+Q3+Q4-Qp1-Qp2-Qρ±Qm (30)±Q k =m a c a (t h -t c )=Q 1 +Q 2 +Q 3 +Q 4 -Q p1 -Q p2 -Q ρ ±Q m (30)

其中,ma为循环风的质量流量,kg/s;ca为空气比热;th为农作物人工气候室循环空调风进入换热器前的来自农作物人工气候室的回风温度或是回风与新风混合的风温,回风口布置在农作物人工气候室作物床的近地面部位;tc为循环空调风在送风口进入农作物人工气候室前的气温,送风口布置在农作物人工气候室上方靠近顶面;Among them, m a is the mass flow rate of the circulating air, kg/s; c a is the air specific heat; t h is the return air temperature or the return air from the crop artificial climate chamber before the circulating air-conditioning air enters the heat exchanger. The air temperature mixed with the fresh air, the return air outlet is arranged near the ground of the crop bed in the crop artificial climate chamber; t c is the temperature of the circulating air-conditioning air before the air supply port enters the crop artificial climate chamber, and the air supply port is arranged above the crop artificial climate chamber near the top;

当th>tc送冷风,当th<tc送热风。When th h > t c , send cold air, when th < t c , send hot air.

附图说明Description of drawings

附图示出了本公开的示例性实施方式,并与其说明一起用于解释本公开的原理,其中包括了这些附图以提供对本公开的进一步理解,并且附图包括在本说明书中并构成本说明书的一部分。The accompanying drawings illustrate exemplary embodiments of the present disclosure and, together with the description, serve to explain the principles of the present disclosure, are included to provide a further understanding of the disclosure, and are incorporated in and constitute the present specification part of the manual.

图1是根据本公开的一个实施方式的农作物人工气候室的补光方法的流程示意图。FIG. 1 is a schematic flowchart of a method for supplementing light in an artificial climate chamber for crops according to an embodiment of the present disclosure.

图2是根据本公开的一个实施方式的农作物人工气候室的结构示意图。FIG. 2 is a schematic structural diagram of an artificial climate chamber for crops according to an embodiment of the present disclosure.

图3是根据本公开的一个实施方式的农作物人工气候室的顶层采用遮光网的结构示意图。3 is a schematic structural diagram of a top layer of an artificial climate chamber for crops using a shading net according to an embodiment of the present disclosure.

图4是根据本公开的一个实施方式的排列整齐的平行矩形的视角系数。FIG. 4 is a viewing angle coefficient of an aligned parallel rectangle according to one embodiment of the present disclosure.

图中附图标记具体为:The reference signs in the figure are:

1 底层1 bottom layer

2 四周围壁2 surrounding walls

3 顶层3 top layers

4 遮光网4 Shading net

5 补偿光灯5 Compensation light

6 风机6 Fans

7 滚筒7 rollers

8 换热器8 heat exchanger

具体实施方式Detailed ways

下面结合附图和实施方式对本公开作进一步的详细说明。可以理解的是,此处所描述的具体实施方式仅用于解释相关内容,而非对本公开的限定。另外还需要说明的是,为了便于描述,附图中仅示出了与本公开相关的部分。The present disclosure will be further described in detail below in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the related content, but not to limit the present disclosure. In addition, it should be noted that, for the convenience of description, only the parts related to the present disclosure are shown in the drawings.

需要说明的是,在不冲突的情况下,本公开中的实施方式及实施方式中的特征可以相互组合。下面将参考附图并结合实施方式来详细说明本公开的技术方案。It should be noted that the embodiments of the present disclosure and the features of the embodiments may be combined with each other unless there is conflict. The technical solutions of the present disclosure will be described in detail below with reference to the accompanying drawings and in conjunction with the embodiments.

除非另有说明,否则示出的示例性实施方式/实施例将被理解为提供可以在实践中实施本公开的技术构思的一些方式的各种细节的示例性特征。因此,除非另有说明,否则在不脱离本公开的技术构思的情况下,各种实施方式/实施例的特征可以另外地组合、分离、互换和/或重新布置。Unless otherwise stated, the illustrated exemplary embodiments/embodiments are to be understood as exemplary features providing various details of some ways in which the technical concept of the present disclosure may be implemented in practice. Therefore, unless otherwise stated, the features of various embodiments/embodiments may be additionally combined, separated, interchanged and/or rearranged without departing from the technical concept of the present disclosure.

在附图中使用交叉影线和/或阴影通常用于使相邻部件之间的边界变得清晰。如此,除非说明,否则交叉影线或阴影的存在与否均不传达或表示对部件的具体材料、材料性质、尺寸、比例、示出的部件之间的共性和/或部件的任何其它特性、属性、性质等的任何偏好或者要求。此外,在附图中,为了清楚和/或描述性的目的,可以夸大部件的尺寸和相对尺寸。当可以不同地实施示例性实施例时,可以以不同于所描述的顺序来执行具体的工艺顺序。例如,可以基本同时执行或者以与所描述的顺序相反的顺序执行两个连续描述的工艺。此外,同样的附图标记表示同样的部件。The use of cross-hatching and/or hatching in the drawings is generally used to clarify boundaries between adjacent components. As such, unless stated, the presence or absence of cross-hatching or shading does not convey or imply specific materials, material properties, dimensions, proportions, commonalities between the illustrated components and/or any other characteristics of the components, any preferences or requirements for attributes, properties, etc. Furthermore, in the drawings, the size and relative sizes of components may be exaggerated for clarity and/or descriptive purposes. When example embodiments may be implemented differently, the specific process sequence may be performed in a different order than described. For example, two consecutively described processes may be performed substantially concurrently or in the reverse order of that described. In addition, the same reference numerals denote the same components.

当一个部件被称作“在”另一部件“上”或“之上”、“连接到”或“结合到”另一部件时,该部件可以直接在所述另一部件上、直接连接到或直接结合到所述另一部件,或者可以存在中间部件。然而,当部件被称作“直接在”另一部件“上”、“直接连接到”或“直接结合到”另一部件时,不存在中间部件。为此,术语“连接”可以指物理连接、电气连接等,并且具有或不具有中间部件。When an element is referred to as being "on" or "over", "connected to" or "coupled to" another element, the element can be directly on, directly connected to, the other element Either directly coupled to the other component, or intermediate components may be present. However, when an element is referred to as being "directly on," "directly connected to," or "directly coupled to" another element, there are no intervening elements present. To this end, the term "connected" may refer to a physical connection, electrical connection, etc., with or without intervening components.

为了描述性目的,本公开可使用诸如“在......之下”、“在......下方”、“在......下”、“下”、“在......上方”、“上”、“在......之上”、“较高的”和“侧(例如,如在“侧壁”中)”等的空间相对术语,从而来描述如附图中示出的一个部件与另一(其它)部件的关系。除了附图中描绘的方位之外,空间相对术语还意图包含设备在使用、操作和/或制造中的不同方位。例如,如果附图中的设备被翻转,则被描述为“在”其它部件或特征“下方”或“之下”的部件将随后被定位为“在”所述其它部件或特征“上方”。因此,示例性术语“在......下方”可以包含“上方”和“下方”两种方位。此外,设备可被另外定位(例如,旋转90度或者在其它方位处),如此,相应地解释这里使用的空间相对描述语。For descriptive purposes, the present disclosure may use words such as "under", "under", "under", "under", "under" Spatially relative terms such as "above," "on," "above," "higher," and "side (eg, as in "sidewall"), etc. , thereby describing the relationship of one element to another (other) element as shown in the figures. In addition to the orientation depicted in the figures, spatially relative terms are intended to encompass different orientations of the device in use, operation, and/or manufacture. For example, if the device in the figures is turned over, elements described as "below" or "beneath" other elements or features would then be oriented "above" the other elements or features. Thus, the exemplary term "below" can encompass both an orientation of "above" and "below." In addition, the device may be otherwise oriented (eg, rotated 90 degrees or at other orientations) and, as such, the spatially relative descriptors used herein should be interpreted accordingly.

这里使用的术语是为了描述具体实施例的目的,而不意图是限制性的。如这里所使用的,除非上下文另外清楚地指出,否则单数形式“一个(种、者)”和“所述(该)”也意图包括复数形式。此外,当在本说明书中使用术语“包含”和/或“包括”以及它们的变型时,说明存在所陈述的特征、整体、步骤、操作、部件、组件和/或它们的组,但不排除存在或附加一个或更多个其它特征、整体、步骤、操作、部件、组件和/或它们的组。还要注意的是,如这里使用的,术语“基本上”、“大约”和其它类似的术语被用作近似术语而不用作程度术语,如此,它们被用来解释本领域普通技术人员将认识到的测量值、计算值和/或提供的值的固有偏差。The terminology used herein is for the purpose of describing particular embodiments and is not intended to be limiting. As used herein, the singular forms "a" and "the" are intended to include the plural forms as well, unless the context clearly dictates otherwise. Furthermore, when the terms "comprising" and/or "comprising" and their variants are used in this specification, it is indicated that the stated features, integers, steps, operations, parts, components and/or groups thereof are present, but not excluded One or more other features, integers, steps, operations, parts, components and/or groups thereof are present or additional. Note also that, as used herein, the terms "substantially," "approximately," and other similar terms are used as terms of approximation and not as terms of degree, as they are used to explain what one of ordinary skill in the art would recognize Inherent deviations from measured, calculated and/or provided values.

图1是根据本公开的一个实施方式的农作物人工气候室的补光方法的流程示意图。FIG. 1 is a schematic flowchart of a method for supplementing light in an artificial climate chamber for crops according to an embodiment of the present disclosure.

如图1所示的农作物人工气候室的补光方法,其包括:As shown in Figure 1, the supplementary light method for the artificial climate chamber of crops includes:

建立农作物人工气候室的能量方程,Establish the energy equation of the artificial climate chamber for crops,

根据所述能量方程,调节照射入农作物人工气候室的光照,使得农作物人工气候室内部的农作物床的受照光合作用光谱能量与室外的农作物床的受照光合作用光谱能量相同,并使得所述农作物人工气候室内部处于预设温度内;According to the energy equation, the light irradiated into the crop artificial climate chamber is adjusted so that the photosynthetic spectral energy of the crop bed inside the crop artificial climate chamber is the same as the photosynthetic spectral energy of the outdoor crop bed, and the said The interior of the crop artificial climate chamber is within the preset temperature;

其中,所述的农作物人工气候室的单位时间能量方程为:Wherein, the unit time energy equation of the crop artificial climate chamber is:

Figure BDA0002885871250000102
Figure BDA0002885871250000102

所述能量方程中,正号为能量输入,负号为能量消耗,单位均为W;Q1为输入到农作物人工气候室内的太阳能量,包括直射和散热太阳光能;Q2为补偿光灯消耗的电能量;Q3为农作物人工气候室内气流均匀化的附加风机消耗的电能量;Q4为玻璃罩对室内的传热量;Qp1、Qp2为农作物床吸收的太阳光和补偿光中的光合作用能量,这部分能量将转化为葡萄糖或淀粉或植物纤维的碳氢氧有机物;Qρ是作物床反射到室外的辐射能量,主要为绿光的能量,

Figure BDA0002885871250000101
±Qk为空调机循环风送给农作物人工气候室冷量或冷量,当输入热量时为正号,输入冷量时为负号;±Qm为农作物人工气候室内的室内空气热容、作物床植株热容和根系土壤的热容吸热或放热量,吸热为负号,放热为正号。In the described energy equation, the positive sign is the energy input, the negative sign is the energy consumption, and the unit is W; Q 1 is the solar energy input into the artificial climate room for crops, including direct sunlight and heat dissipation solar energy; Q 2 is the compensation light lamp Electric energy consumed; Q 3 is the electric energy consumed by the additional fan for uniform air flow in the artificial climate of crops; Q 4 is the heat transfer from the glass cover to the room; Q p1 and Q p2 are the sunlight absorbed by the crop bed and the compensation light Q ρ is the radiant energy reflected from the crop bed to the outdoors, mainly green light energy,
Figure BDA0002885871250000101
±Q k is the cooling or cooling capacity of the circulating air from the air conditioner to the artificial climate room for crops, positive sign when heat is input, and negative when cooling is input; ±Q m is the heat capacity of indoor air in the artificial climate room for crops, The heat capacity of the crop bed plant and the root soil heat capacity endothermic or exothermic, the endothermic is negative, and the exothermic is positive.

当农作物人工气候室达到平衡态时,主要是农作物人工气候室的空气热容的温度波动需要的热量。When the crop artificial climate chamber reaches the equilibrium state, it is mainly the heat required by the temperature fluctuation of the air heat capacity of the crop artificial climate chamber.

图2是根据本公开的一个实施方式的农作物人工气候室的结构示意图。FIG. 2 is a schematic structural diagram of an artificial climate chamber for crops according to an embodiment of the present disclosure.

本公开的农作物人工气候室,模型为长方形的玻璃房,东西向宽6±0.1m、南北向深4±0.1m,高3m,底层1为农作物床,四周围壁2和顶层3是双层中空玻璃隔层,玻璃斜坡顶层北高南低;配备有制冷供热系统和风循环系统,室内空气循环经过换热器8获得冷量或热量,换热器8是制冷工质做制冷循环时制冷机的蒸发器,或制冷工质做热泵循环时凝结器;循环风道在回风口处增设有新风口,在回风口对面玻璃壁开有排风口,新风口和排风口管道里都配有闸片调节阀;玻璃房顶层上方配置有透光率π为60%的遮阳网4;遮阳网不用时由滚筒7收卷起来;室内配有LED补偿光灯5,以及测量人工气候室内的温度、湿度、室外温度、风循环回路送、回风温度的测头,室内、外太阳全辐照强度仪和信号收集处理控制系统;人工气候室内中部配有气流均匀化的风机6。The crop artificial climate chamber of the present disclosure is modeled as a rectangular glass room, with a width of 6±0.1m from east to west, a depth of 4±0.1m from north to south, and a height of 3m. The bottom layer 1 is a crop bed, and the surrounding walls 2 and the top layer 3 are double layers Insulating glass partition, the top layer of the glass slope is high in the north and low in the south; equipped with a cooling and heating system and an air circulation system, the indoor air circulates through the heat exchanger 8 to obtain cold or heat, and the heat exchanger 8 is used for refrigeration when the refrigerant is used as a refrigeration cycle. The evaporator of the machine, or the condenser when the refrigeration working medium is used as a heat pump cycle; the circulating air duct is equipped with a new air outlet at the return air outlet, and an air outlet is opened on the glass wall opposite the return air outlet. There is a shutter regulating valve; a sunshade net 4 with a light transmittance π of 60% is arranged on the top of the glass room; Measuring heads for temperature, humidity, outdoor temperature, air circulation loop supply and return air temperature, indoor and outdoor solar irradiance meters and signal collection and processing control systems; the center of the artificial climate room is equipped with a fan 6 for air uniformity.

本公开中,通过对光谱能量的品质特性分析,确定农作物光合作用和补偿光的光谱为可见光中除绿光外的辐射能,以蓝紫光(380-420nm)和蓝光(420-450nm)为主,红光(605-670nm)为辅;太阳辐射可见光(380-780nm)占太阳光辐射能的份额为47.29%,扣除绿光(500-560nm)所占的

Figure BDA0002885871250000111
能被植物吸收的光合作用的能量份额为
Figure BDA0002885871250000112
In the present disclosure, by analyzing the quality characteristics of spectral energy, it is determined that the spectrum of photosynthesis and compensation light of crops is the radiant energy of visible light except green light, mainly blue-violet light (380-420nm) and blue light (420-450nm) , supplemented by red light (605-670nm); solar radiation visible light (380-780nm) accounts for 47.29% of solar radiation energy, deducting green light (500-560nm)
Figure BDA0002885871250000111
The share of photosynthetic energy that can be absorbed by plants is
Figure BDA0002885871250000112

在所述能量方程中,调节农作物人工气候室温度所消耗的电功率:In the energy equation, the electrical power consumed to adjust the temperature of the climate chamber for crops is:

P=Q2+Q3+Qk/COP (2)P=Q 2 +Q 3 +Q k /COP (2)

其中,COP为制冷/供热和风循环能量调节系统的性能系数;Among them, COP is the coefficient of performance of the cooling/heating and air circulation energy regulation system;

农作物人工气候室内的室内空气温度、湿度由空调机循环风系统调控送入室内的进风温度、湿度完成,循环风回路在进风口前配置有换热器,调节进风温度;循环风回路的回风配置有新风调节口。The indoor air temperature and humidity in the crop artificial climate room are controlled by the circulating air system of the air conditioner to control the temperature and humidity of the inlet air sent into the room. The circulating air circuit is equipped with a heat exchanger in front of the air inlet to adjust the inlet air temperature; The return air is equipped with a fresh air adjustment port.

太阳辐射穿透玻璃壁和玻璃顶进入农作物人工气候室前有一部分辐射能Gout,ρ被玻璃反射,有部分Gout,α被玻璃吸收,余下的进入农作物人工气候室(玻璃试验房)内,这部分能量记作Q1Before the solar radiation penetrates the glass wall and glass roof and enters the artificial climate chamber of crops, there is a part of the radiant energy G out, ρ is reflected by the glass, part of G out, α is absorbed by the glass, and the rest enters the artificial climate chamber of crops (glass test room) , this part of the energy is recorded as Q 1 .

当所述农作物人工气候室在未被遮挡时:When the crop artificial climate chamber is not shaded:

Q1=Gin,θA0=Gout,θτA0=(Gbcosθ+Gd)τA0 (3)Q 1 =G in, θ A 0 =G out, θ τA 0 =(G b cosθ+G d )τA 0 (3)

其中,Gin,θ和Gout,θ分别为农作物人工气候室内部和外部的水平面受到太阳辐照强度,单位为W/m2,用放置在室内、外水平面上的太阳总辐照仪测量值,下角标in表示室内,out表示室外,θ表示太阳光线的天顶角;τ为玻璃的平均透光率,玻璃的透光率τ与反射率ρ和吸收率α的三者关系为τ+ρ+α=1,一般τ=0.85,ρ=0.1,α=0.05;A0为农作物人工气候室的农作物床的面积,单位为m2,本公开中为4×25m2=100m2;Gb为直射太阳辐射强度,用直射太阳辐射计测得;Gd为散射太阳辐射强度,为用太阳全辐射计测量值减去直射太阳辐射计测量值的差值;直射太阳辐射强度照射在水平面的作物床的辐射能量用Gbcosθ计算,其中θ为太阳入射线与水平面法线的夹角,称天顶角;对于水平面来说,散射辐射来自天空半球向的照射;直射太阳辐射强度与散射太阳的辐射强度的比例份额,与天空的云层灰度有关,可以从太阳能利用等专门资料中查取,或用测量法获得;作为算例分析,取Gb/Gd=6/4,Gb=0.6Gout,Gd=0.4Gout,Gout=1.0kW;θ=0为正午,正午的正射太阳总辐照强度,可以用Gout,θ=0=Gout表示;当正午θ=0时,水平面受到的太阳辐照强度Gout,0=Gout=1.0W/m2。太阳辐照强度,在大气层外为G0=1368W/m2称太阳辐射常数,实际的太阳辐照强度与太阳光穿过大气层的厚度,大气中含的水汽、二氧化碳浓度有关,本公开中通过安装在室内作物床上方和室外玻璃房顶水平架上的太阳全辐照强度仪测量室内作物床上和室外的太阳辐照强度Gin,θ和Gout,θAmong them, G in, θ and G out, θ are the solar radiation intensity on the horizontal plane inside and outside the artificial climate chamber of crops, respectively, the unit is W/m 2 . value, the subscript in represents indoor, out represents outdoor, θ represents the zenith angle of sunlight; τ is the average transmittance of glass, and the relationship between the transmittance τ of glass, reflectivity ρ and absorption rate α is τ +ρ+α=1, generally τ=0.85, ρ=0.1, α=0.05; A 0 is the area of the crop bed of the crop artificial climate chamber, the unit is m 2 , in this disclosure, it is 4×25m 2 =100m 2 ; G b is the direct solar radiation intensity, which is measured with a direct solar radiation meter; G d is the scattered solar radiation intensity, which is the difference between the measured value of the total solar radiation meter minus the measured value of the direct solar radiation meter; the direct solar radiation intensity is irradiated at The radiant energy of the crop bed on the horizontal plane is calculated by G b cos θ, where θ is the angle between the incoming solar ray and the normal to the horizontal plane, called the zenith angle; for the horizontal plane, the scattered radiation comes from the hemisphere of the sky; the intensity of direct solar radiation The proportional share of the radiation intensity of the scattered sun is related to the gray level of the cloud layer in the sky, which can be obtained from special data such as solar energy utilization, or obtained by measurement methods; as an example analysis, take G b /G d =6/4 , G b =0.6G out , G d =0.4G out , G out =1.0kW; θ=0 is noon, and the total solar radiation intensity at noon can be represented by G out, θ=0 =G out ; When θ=0 at noon, the solar radiation intensity G out received by the horizontal plane, 0 =G out =1.0W/m 2 . The solar radiation intensity is G 0 =1368W/m 2 outside the atmosphere. It is called the solar radiation constant. The actual solar radiation intensity is related to the thickness of the sunlight passing through the atmosphere, and the concentration of water vapor and carbon dioxide contained in the atmosphere. The total solar irradiance meter installed above the indoor crop bed and on the outdoor glass roof horizontal frame measures the solar irradiance G in, θ and G out, θ on the indoor crop bed and outdoors.

Q1,θ=0=GinA0=Gout(atcosθ+ad)τA0=1×(0.6+0.4)×0.85×100=85kW;Q 1, θ=0 =G in A 0 =G out (at cosθ +ad ) τA 0 =1×(0.6+0.4)×0.85×100=85kW;

Q1,θ=30°=Gout(atcos 75°+ad)τA0=1×(0.6cos 30°+0.4)×0.85×100=78.2kW;Q 1, θ=30° =G out (at cos 75°+ad )τA 0 =1×( 0.6cos 30°+0.4)×0.85×100= 78.2kW ;

Q1,θ=75°=Gout(atcos 75°+ad)τA0=1×(0.6cos 75°+0.4)×0.85×100=49.5kW;Q 1, θ=75° =G out (at cos 75°+ad )τA 0 =1×( 0.6cos 75°+0.4)×0.85×100= 49.5kW ;

也就是说,在正午时,农作物床收到的太阳辐射能最大。That is, at noon, the crop beds receive the greatest amount of solar radiation.

当农作物人工气候室通过顶棚遮光网进行遮光时,Q1记为Q1,π,(在下角标中添加π表示)农作物床上的受照太阳辐射能包括直射辐射能和散射辐射能两部分,计算式为:When the crop artificial climate chamber is shaded by the roof shading net, Q 1 is denoted as Q 1, π , (indicated by adding π in the subscript), the irradiated solar radiation energy on the crop bed includes direct radiation energy and scattered radiation energy. The calculation formula is:

Q1,π=[Gout,θ,b(1-πb)+Gd(1-πF21)]τA0 (4)Q 1, π = [G out, θ, b (1-π b )+G d (1-πF 21 )]τA 0 (4)

其中,Gout,θ,b为在无遮光时太阳入射角为θ的直射辐射能,πb为遮光网减少的直射辐射能份额,为作物床被遮光网遮挡的面积份额与遮光度的乘积,具体参数要根据遮光网的几何位置和尺寸计算;举例:遮光网的顶棚与作物床平行高度为Z,作物床宽度为xb,遮光网宽度为xz,参考图3,从遮光网顶棚左端射到作物床的右端光线La的天顶角为θa,从遮光网顶棚左端射到作物床的左端光线Lb的天顶角为θb,当θ<θa时遮光网对直射太阳的拦截有减太阳直射辐射作用,当θ≥θa时太阳直射辐射不受遮光网影响,因为太阳高度低;当θ<θa以后,随θ的继续减小,太阳高度增高,在作物床上出现遮光网的阴影面积,天顶角为θ的光线La在作物床上产生的阴影宽度xπ表示,Among them, G out, θ, b is the direct radiant energy of the sun incident angle θ when there is no shading, π b is the direct radiant energy share reduced by the shading net, and is the product of the area share of the crop bed blocked by the shading net and the shading degree , the specific parameters should be calculated according to the geometric position and size of the shading net; for example: the height of the ceiling of the shading net parallel to the crop bed is Z, the width of the crop bed is x b , and the width of the shading net is x z , refer to Figure 3, from the ceiling of the shading net The zenith angle of the light L a from the left end to the right end of the crop bed is θ a , and the zenith angle of the light L b from the left end of the shading net roof to the crop bed is θ b . When θ < θ a , the shading net is directed toward The interception of the sun has the effect of reducing the direct solar radiation. When θ≥θ a , the direct solar radiation is not affected by the shading net, because the sun height is low; when θ < θ a , as θ continues to decrease, the sun height increases. The shadow area of the shading net appears on the bed, and the shadow width x π produced by the light L a with the zenith angle θ on the crop bed is expressed as,

xπ=Z tanθa-Z tanθ=xa-xθx π =Z tan θ a -Z tan θ = x a -x θ ;

xa=Z tanθa,xθ=Z tanθ,xb=Z tanθbx a = Z tan θ a , x θ = Z tan θ , x b = Z tan θ b ;

Gout,θ,b(1-πb)=Gout,b (θ≥θab=0 (5a)G out, θ, b (1-π b )=G out, b (θ≥θ ab =0 (5a)

Figure BDA0002885871250000131
Figure BDA0002885871250000131

Gout,θ,b(1-πb)=Gout,b(1-π) (θb>θ,θ=0) πb=π (5c)G out, θ, b (1-π b )=G out, b (1-π) (θ b >θ, θ=0) π b =π (5c)

散射辐射能Gd(1-πF21)的πF21为遮光网在半球空间辐射中占有的份额,F21视角系数为作物床平面所拦截的从遮光网顶棚面来辐射份额;The πF 21 of the scattered radiation energy G d (1-πF 21 ) is the share of the shading net in the hemispherical space radiation, and the F 21 viewing angle coefficient is the radiation share from the roof surface of the shading net intercepted by the crop bed plane;

所以,根据太阳高度不同,天顶角θ不同,选择式(5a)或(5b)或(5c)代入式(4),可计算有遮光时进入农作物人工气候室的太阳辐射能Q1,πTherefore, according to the different height of the sun and the different zenith angle θ, choose formula (5a) or (5b) or (5c) and substitute it into formula (4) to calculate the solar radiation energy Q 1, π that enters the artificial climate chamber of crops when there is shading ;

Figure BDA0002885871250000132
Figure BDA0002885871250000132

当θ=0时,When θ=0,

Q1,π,θ=0=[Gb(1-π)+Gd(1-πF21)]τA0 (4a)Q 1, π, θ=0 = [G b (1-π)+G d (1-πF 21 )]τA 0 (4a)

作物床的面积为x=xb=12.5m,y=8m,Z=3.5m,xz=13.5m,xa=13m,根据x/Z=3.57,y/z=2.29由图2得F12=0.52,令π=0.6,采用遮光措施后,当正午时θ=0时,单位时间输入到玻璃实验房内的太阳的能量输入到玻璃实验房内的太阳的能量为The area of the crop bed is x = x b = 12.5m, y = 8m, Z = 3.5m, x z = 13.5m, x a = 13m, according to x/Z = 3.57, y/z = 2.29 F from Figure 2 12 = 0.52, let π = 0.6, after adopting shading measures, when θ = 0 at noon, the energy of the sun input into the glass laboratory room per unit time input to the sun energy in the glass laboratory room is:

Q1,θ=0,π=GinA0=[0.6(1-0.6)+0.4(1-0.6×0.52)]×0.85×100=43.8kW;Q 1, θ=0, π =G in A 0 =[0.6(1-0.6)+0.4(1-0.6×0.52)]×0.85×100=43.8kW;

θ=30°时,When θ=30°,

Figure BDA0002885871250000133
Figure BDA0002885871250000133

θ=75°时,Q1,θ=75°=84.7kW,无需遮拦。When θ=75°, Q 1, θ=75° =84.7kW, no need to block.

当采用红外反射半透明膜时的Q1计算,记作

Figure BDA0002885871250000134
Q1 calculation when using infrared reflective translucent film, denoted as
Figure BDA0002885871250000134

当采用铺设于农作物人工气候室顶层玻璃上面的红外反射半透明膜时,可见光的遮光度为πp=0.1,占太阳辐射的份额

Figure BDA0002885871250000141
红外辐射反射膜的对波长λ≥780nm的光谱辐射遮光度为πh=0.9,占太阳辐射的份额
Figure BDA0002885871250000142
东西南北四围玻璃无遮拦;采用红外反射半透明膜时,式(4)的太阳直射辐射能和散射辐射能,应当分解为可见光和红外辐射两部分能量,并分别使用不同的遮光率πp和πh,则式(4)转化为使用红外反射半透明膜时进入作物人工实验室的太阳辐射能为:When using the infrared reflective translucent film laid on the top glass of the crop artificial climate chamber, the shading degree of visible light is π p = 0.1, which accounts for the share of solar radiation
Figure BDA0002885871250000141
The shading degree of the infrared radiation reflective film to the spectral radiation of wavelength λ≥780nm is π h = 0.9, accounting for the share of solar radiation
Figure BDA0002885871250000142
The glass is unobstructed in the east, west, north and south; when infrared reflective translucent film is used, the direct solar radiation energy and scattered radiation energy of formula (4) should be decomposed into visible light and infrared radiation energy, and use different shading rates π p and π h , then the formula (4) is transformed into the solar radiation energy entering the artificial laboratory of crops when the infrared reflective translucent film is used as:

Figure BDA0002885871250000143
Figure BDA0002885871250000143

整理为可见光和红外辐射两部分表示,则计算式为

Figure BDA0002885871250000144
Organized into two parts, visible light and infrared radiation, the calculation formula is
Figure BDA0002885871250000144

式(7)的等号右边的第一项为可见光部,第二项为红外辐射部;The first term on the right side of the equal sign of formula (7) is the visible light part, and the second term is the infrared radiation part;

正午θ=0时,πb,p=πp,πb,h=πh所以式(7)化作(7a)或(7b)At noon θ=0, π b, p = π p , π b, h = π h , so formula (7) becomes (7a) or (7b)

Figure BDA0002885871250000145
Figure BDA0002885871250000145

Figure BDA0002885871250000146
Figure BDA0002885871250000146

其中,可见光的入室能量为Among them, the entering energy of visible light is

Figure BDA00028858712500001410
Figure BDA00028858712500001410

Figure BDA0002885871250000147
Figure BDA0002885871250000147

太阳红外辐射的入室能量为The incoming energy of solar infrared radiation is

Figure BDA00028858712500001411
Figure BDA00028858712500001411

Figure BDA0002885871250000148
Figure BDA0002885871250000148

与无遮光方案相比,节省空调冷量为Compared with the no shading scheme, the air-conditioning cooling capacity is saved by

Figure BDA0002885871250000149
Figure BDA0002885871250000149

Figure BDA0002885871250000159
Figure BDA0002885871250000159

其中可见光减少量只有Among them, the visible light reduction is only

Figure BDA0002885871250000152
Figure BDA0002885871250000152

主要是远红外辐射能的减少,即Mainly the reduction of far-infrared radiant energy, namely

Figure BDA0002885871250000153
Figure BDA0002885871250000153

红外反射遮光膜与遮光网方案相比,传入室内的太阳能辐射量差值为:Compared with the shading net scheme, the difference in the amount of solar radiation entering the room is as follows:

Figure BDA0002885871250000154
Figure BDA0002885871250000154

式(13)中,遮光网方案的可见光偏少量为:In formula (13), the partial amount of visible light in the shading net scheme is:

Figure BDA0002885871250000155
Figure BDA0002885871250000155

扣除绿光份额后,遮光网方案的作物光合作用辐射能偏少量为:After deducting the green light share, the partial amount of crop photosynthesis radiant energy in the shading net scheme is:

Figure BDA0002885871250000156
Figure BDA0002885871250000156

由此,相比于遮光网方案,采用红外反射遮光膜的方案:Therefore, compared with the shading net scheme, the scheme of using the infrared reflective shading film:

减少补偿光的功率:Reduce the power of the compensation light:

ΔQπ,VL=0.3924×16.24/0.4729=13.47kW (15a)ΔQ π, VL = 0.3924 × 16.24/0.4729 = 13.47kW (15a)

减少补光灯的电功率为:To reduce the electric power of the fill light is:

ΔP2,π-ρ=ΔQπ,VLd=13.47/0.85=15.8kW (16)ΔP 2, π-ρ = ΔQ π, VLd = 13.47/0.85 = 15.8kW (16)

增加远红外辐射能:Increase far-infrared radiant energy:

Figure BDA0002885871250000157
Figure BDA0002885871250000157

绿光辐射能比遮光网的增多:The radiant energy of green light is more than that of the shading net:

Figure BDA0002885871250000158
Figure BDA0002885871250000158

按空调机性能系数COP=3.2计算,红外反射遮光膜的方案比遮光网的方案节省电功率为:Calculated according to the coefficient of performance of the air conditioner COP=3.2, the scheme of infrared reflection shading film saves electric power compared with the scheme of shading net as follows:

ΔP2,π-p=ΔP2,π-ρ-(ΔQπ,IR-ΔQπ,ρ)/COP=15.8-(10.86-1.66)/3.2=12.9kW (19)ΔP 2,π-p =ΔP 2,π- ρ-(ΔQπ ,IR -ΔQπ )/COP=15.8-(10.86-1.66)/3.2=12.9kW (19)

Qp1是作物床的作物吸收从太阳光的能量,记αp为植物的光合作用光谱辐射能吸收率,则作物床吸收的光合作用能量为Q p1 is the energy absorbed by the crops in the crop bed from sunlight, and α p is the photosynthetic spectral radiant energy absorption rate of the plant, then the photosynthetic energy absorbed by the crop bed is

Figure BDA0002885871250000161
Figure BDA0002885871250000161

其中,

Figure BDA0002885871250000162
为太阳光中被植物吸收的光合作用的能量份额,
Figure BDA0002885871250000163
αp为植物的光合作用光谱辐射能吸收率,ξ为光合作用从光能变成化学能的效率;由于植物的光合作用是光量子作用,是辐射能中的可做功的有效能起作用,光量子有效能占有率ξ与波长的关系为in,
Figure BDA0002885871250000162
is the share of photosynthetic energy absorbed by plants in sunlight,
Figure BDA0002885871250000163
α p is the spectral radiant energy absorption rate of the photosynthesis of plants, ξ is the efficiency of photosynthesis from light energy to chemical energy; because the photosynthesis of plants is the action of photons, it is the effective energy that can do work in the radiant energy, and the photons The relationship between the effective energy occupancy rate ξ and the wavelength is

Figure BDA0002885871250000164
Figure BDA0002885871250000164

式中,c3是光谱特征温度方程常数,c3=λTλ=5.33016×10-3m·K;当取环境温度T0=298K,计算得到,蓝紫光的ξ=0.9787,蓝光的ξ=0.976-0.9748,红光的ξ=0.964-0.9625;对植物来说,蓝紫光、蓝光和红光能被植物的叶绿素接收,而且其光量子能量中包含的可做功能,能保证在室温下光合作用的内核联合体产生葡萄糖的能量转化效率到0.93-0.92之间;式(8)计算的是理想光合作用效率,即最高效率;实际的光合作用效率也很高,蓝光光合作用效率超过90%,红光的光合作用效率达75-85%;植物的光合作用光谱辐射能吸收率αp与作物生长的状况,植株的大小,绿叶受光面积等因素有关,大面积实验有报告作物光合作用的效率约0.3-0.4;作物光谱能量吸收率应该做更多实验研究统计归纳,本实施例建议取αpξ=0.35;In the formula, c 3 is the spectral characteristic temperature equation constant, c 3 =λT λ =5.33016×10 -3 m·K; when the ambient temperature T 0 =298K, it is calculated that ξ=0.9787 for blue-violet light, ξ= ξ= for blue light 0.976-0.9748, ξ=0.964-0.9625 of red light; for plants, blue-violet light, blue light and red light can be received by the chlorophyll of plants, and the functions contained in the light quantum energy can ensure photosynthesis at room temperature The energy conversion efficiency of the core complex to produce glucose is between 0.93-0.92; formula (8) calculates the ideal photosynthesis efficiency, that is, the highest efficiency; the actual photosynthesis efficiency is also very high, and the blue light photosynthesis efficiency exceeds 90%, The photosynthetic efficiency of red light reaches 75-85%; the photosynthetic spectral radiant energy absorption rate α p of plants is related to the conditions of crop growth, the size of the plant, the light-receiving area of green leaves and other factors. Large-scale experiments have reported the efficiency of crop photosynthesis About 0.3-0.4; crop spectral energy absorption rate should be done more experimental research and statistical summary, in this embodiment, it is recommended to take α p ξ = 0.35;

在正午,无遮光时的Qp1,记作Qp1,θ=0 At noon, Q p1 when there is no shading, denoted as Q p1, θ=0

Figure BDA0002885871250000165
Figure BDA0002885871250000165

在使用遮光网时:When using shade nets:

Figure BDA0002885871250000166
Figure BDA0002885871250000166

在使用红外反射遮光膜时,When using infrared reflective shading film,

Figure BDA0002885871250000167
Figure BDA0002885871250000167

所述的作物床的受照光合作用光谱能量不减原则,设计匹配的补偿光和对补偿光调控的原则,具体化为补偿光是由LRD灯发射蓝光(包括蓝紫光)、红光;根据太阳光中的蓝光(包括蓝紫光)、红光所占的辐射能份额,蓝紫光

Figure BDA0002885871250000168
蓝光的
Figure BDA0002885871250000169
阳红光的
Figure BDA00028858712500001610
蓝紫光+蓝光与红光的占比为8.12/8.055;所以,补偿光的蓝光(包括蓝紫光)的功率与红光的功率配比为The principle of the non-reduction of the spectral energy of the photosynthesis of the crop bed, the principle of designing matching compensation light and regulating the compensation light, is embodied as the compensation light is emitted by the LRD lamp to emit blue light (including blue-violet light) and red light; according to The radiant energy share of blue light (including blue-violet light) and red light in sunlight, blue-violet light
Figure BDA0002885871250000168
Blu-ray
Figure BDA0002885871250000169
sunny
Figure BDA00028858712500001610
The ratio of blue-violet light + blue light to red light is 8.12/8.055; therefore, the ratio of the power of blue light (including blue-violet light) of the compensation light to the power of red light is

Figure BDA0002885871250000171
Figure BDA0002885871250000171

补偿光量Qp2,被植物吸收的补偿光量Qp2,α,补光灯功率Q2的计算:Compensation light quantity Q p2 , compensation light quantity absorbed by plants Q p2,α , calculation of fill light power Q 2 :

能量方程(1)的补偿光灯所产生的光合作用光谱能量Q2为室外、内的可见光光谱段的能量差:The photosynthesis spectral energy Q2 produced by the compensation light of the energy equation (1) is the energy difference between the outdoor and indoor visible light spectrum:

Figure BDA0002885871250000172
Figure BDA0002885871250000172

Figure BDA0002885871250000173
Figure BDA0002885871250000173

ηd是补偿光灯的电光转化率,本算例ηd=0.80;η d is the electro-optical conversion rate of the compensation light, in this example η d = 0.80;

无遮光且正午时的补偿光功率量Q2,θ=0、被吸收的Qp2,θ=0的计算:Compensation optical power quantity Q 2, θ=0 and absorbed Q p2, θ=0 at noon without shading:

Figure BDA00028858712500001712
Figure BDA00028858712500001712

Qp2=ηdQ2αξ=0.85×6.94×0.35=2.07 (23a)Q p2d Q 2 αξ=0.85×6.94×0.35=2.07 (23a)

遮光网遮光且正午时的补偿光功率Q2,π,θ=0、被吸收的Qp2,π,θ=0的计算:Compensation optical power Q 2, π, θ=0 and absorbed Q p2, π, θ=0 at noon when the shading net is shading:

当采用遮光网时,且正午时补光灯的功率Q2,π,θ=0和被农作物吸收的能量Qp2,π,θ=0分别为:When the shading net is used, and the power Q 2, π, θ=0 of the fill light at noon and the energy Q p2, π, θ=0 absorbed by the crops are:

Figure BDA0002885871250000174
Figure BDA0002885871250000174

Qp2,π,θ=0=ηdQ2,π,θ=0αξ=0.85×26.1×0.35=7.77kW (23b)Q p2, π, θ=0 = η d Q 2, π, θ=0 αξ=0.85×26.1×0.35=7.77kW (23b)

当采用红外反射遮光膜时,且正午时的补偿光功率

Figure BDA0002885871250000175
阳被农作物吸收的能量
Figure BDA0002885871250000176
When using infrared reflective shading film, and the compensation optical power at noon
Figure BDA0002885871250000175
Yang energy absorbed by crops
Figure BDA0002885871250000176

Figure BDA0002885871250000177
Figure BDA0002885871250000177

Figure BDA0002885871250000178
Figure BDA0002885871250000178

Qρ为农作物人工气候室反射的辐射能,主要被反射的是绿光,

Figure BDA0002885871250000179
Q ρ is the radiant energy reflected by the artificial climate chamber of crops, and the green light is mainly reflected,
Figure BDA0002885871250000179

Figure BDA00028858712500001710
Figure BDA00028858712500001710

当无遮光θ=0时的绿光反射量,记作Qρ,θ=0When there is no shading θ=0, the green light reflection amount is denoted as Q ρ, θ=0 ;

Figure BDA00028858712500001711
Figure BDA00028858712500001711

当采用遮光网遮光时,且θ=0,遮光度π=0.6时的绿光反射量,记作Qρ,θ=0,π=0.6When the shading net is used for shading, and θ=0, the green light reflection amount when the shading degree π=0.6 is denoted as Q ρ, θ=0, π=0.6 ;

Figure BDA0002885871250000181
Figure BDA0002885871250000181

当采用红外反射膜遮光时,可见光遮光度为πp=0.1,红外遮光度为πph=0.85,θ=0时的绿光反射量,记作Qρ,θ=0,π=0.1When the infrared reflective film is used for shading, the visible light shading degree is π p = 0.1, the infrared shading degree is π ph = 0.85, and the green light reflection amount when θ = 0 is denoted as Q ρ, θ = 0, π = 0.1 ,

Figure BDA0002885871250000182
Figure BDA0002885871250000182

Q4为玻璃罩对室内的传热量,在白天,Q4等于玻璃房的玻璃吸收的太阳辐射能Qout,α=Qoutα,减去玻璃对室外的放热量Q4,out,工程计算允许假定Q4,out=Q4;玻璃罩吸收的太阳辐射能,等于室外太阳辐射能,扣除被玻璃反射掉的太阳辐射能Qout,ρ=Qoutρ和进入室内的太阳辐射能Qin,Qin=Gout(1-τ-ρ)A0,于是在白天因为吸收了太阳辐射而产生热量,传热给农作物人工气候室内的热量根据方程计算式为,Q 4 is the heat transfer from the glass cover to the room. In the daytime, Q 4 is equal to the solar radiation energy Q out absorbed by the glass of the glass room, α = Q out α, minus the heat released by the glass to the outdoor Q 4,out , engineering calculation It is allowed to assume that Q 4 , out = Q 4 ; the solar radiation energy absorbed by the glass cover is equal to the outdoor solar radiation energy, after deducting the solar radiation energy Q out reflected by the glass, ρ = Q out ρ and the solar radiation energy entering the room Qin , Q in =G out (1-τ-ρ)A 0 , so in the daytime heat is generated due to the absorption of solar radiation, and the heat transferred to the artificial climate room for crops is calculated according to the equation as,

Q4=0.5Gout(1-τ-ρ)A0=0.5(Gbcosθ+Gd)αAo (26)Q 4 =0.5G out (1-τ-ρ)A 0 =0.5(G b cosθ+G d )αA o (26)

当正午θ=0时,When noon θ = 0,

Q4=0.5×(0.6+0.4)×0.05×100=2.5kW (26a)Q 4 =0.5×(0.6+0.4)×0.05×100=2.5kW (26a)

当早晨θ=75°时When θ=75° in the morning

Q4=0.5×1000×(0.6cos 75°+0.4)×0.05×100=1.39kW (26b)Q 4 =0.5×1000×(0.6cos 75°+0.4)×0.05×100=1.39kW (26b)

夜晚没有太阳辐射,则There is no solar radiation at night, then

Q4=KA(Tg1-T)=KA(Tout-Tg2) (27)Q 4 =KA(T g1 -T)=KA(T out -T g2 ) (27)

式中K为玻璃壁对空气的平均传热系数,A为玻璃房的玻璃壁面积,Tg1、Tg2分别为室内、外侧玻璃温度,T、Tout分别为室内、外空气温度。In the formula, K is the average heat transfer coefficient of the glass wall to the air, A is the glass wall area of the glass room, T g1 and T g2 are the indoor and outer glass temperatures, respectively, and T and T out are the indoor and outdoor air temperatures, respectively.

Qm为农作物人工气候室气温波动的热容吸热项,Q m is the heat capacity and heat absorption term of the temperature fluctuation of the artificial climate room for crops,

Qm=MacadTa/dt+MfcfdTf/dt+MscsdTs/dt (28)Q m =M a c a dT a /dt+M f c f dT f /dt+M s c s dT s /dt (28)

式中的Ma、Mf、Ms分别为农作物人工气候室内的空气、作物床秸秆、作物床的植物根系土壤的质量,ca、cf、cs分别为农作物人工气候室内的空气、作物床秸秆、作物床的植物根系土壤的比热,Ma≈Mf<<Ms,所以Mscs的热容是农作物人工气候室的热沉,其温度变化不敏感,当植物根系土壤温度达到设定值后,温度控制只要保留空气和作物床植株的热容波动项;例如,根系的土壤热容量很大,以0.4米深度的土壤层,0.6米高的作物层,3米高的农作物人工气候室,土层质量M1=1300kg/m3×0.4m×100m2=52000kg,含水土壤比热容c1=3.5kJ/(kg·K),土壤的热容为M1c1=182000kJ/K;In the formula, Ma , Mf , and Ms are the quality of the air, crop bed straw, and plant root soil in the crop artificial climate room, respectively, ca , cf , and cs are the air in the crop artificial climate room, The specific heat of crop bed straw and plant root soil in crop bed, M a ≈ M f <<M s , so the heat capacity of M s c s is the heat sink of the artificial climate chamber of crops, which is not sensitive to temperature changes. After the soil temperature reaches the set value, the temperature control only needs to keep the heat capacity fluctuation terms of the air and the crop bed plant; In the artificial climate chamber for crops, the soil layer quality M 1 =1300kg/m 3 ×0.4m×100m 2 =52000kg, the specific heat capacity of the water-containing soil c 1 =3.5kJ/(kg·K), the heat capacity of the soil is M 1 c 1 = 182000kJ/K;

作物层的质量M2=5kg/m3×0.5×100m3=250kg,湿作物的比热容c2=2.5kJ/(kg·K),M2c2=625kJ/K;The mass of the crop layer M 2 =5kg/m 3 ×0.5×100m 3 =250kg, the specific heat capacity of the wet crop c 2 =2.5kJ/(kg·K), M 2 c 2 =625kJ/K;

空气层的质量M3=1.3kg/m3×3×100m3=390kg,空气的比热容c3=1.1kJ/(kg·K),M3c3=429kJ/KMass of air layer M 3 =1.3kg/m 3 ×3×100m 3 =390kg, specific heat capacity of air c 3 =1.1kJ/(kg·K), M 3 c 3 =429kJ/K

所以,空气和作物床的热容仅仅占总热容的0.58%,而植物根系土壤层的热容占总热容的99.4%。Therefore, the heat capacity of air and crop bed only accounts for 0.58% of the total heat capacity, while the heat capacity of the plant root soil layer accounts for 99.4% of the total heat capacity.

当农作物人工气候室的室内空气温度控制要求30分钟内允许波动1℃,植株和空气的热容基本相同,Qm用简化式计算When the indoor air temperature control of the artificial climate room for crops requires a fluctuation of 1°C within 30 minutes, the heat capacity of the plant and the air is basically the same, and Q m is calculated by the simplified formula

Qm=(Mafcaf)dTa/dt (29)Q m =(M af c af )dT a /dt (29)

其中Mafcaf=Maca+Mfcfwhere M af c af =M a c a +M f c f ;

如果室内空气温度5分钟波动1度,则:If the indoor air temperature fluctuates by 1 degree in 5 minutes, then:

Qm=MfcfdTf/dt=(429+625)×1/1800=0.41kW (29a)Q m =M f c f dT f /dt=(429+625)×1/1800=0.41kW (29a)

所以,当农作物人工气候室进入精密温度调控时,Qm可以忽略不计。Therefore, when the crop artificial climate chamber enters into precise temperature regulation, Q m can be neglected.

所述的农作物人工气候室的能量平衡,是由制冷供热系统和风循环系统完成;所述的制冷供热系统,采用压缩式制冷机的蒸发器与循环于农作物人工气候室的循环风进行换热,向农作物人工气候室的提供冷量,平衡太阳辐射进入农作物人工气候室的过多热量,保持室内空气温度在设计温度的许可波动范围;当夜间,农作物人工气候室对外散热,室内气温有下降趋势时,制冷工质反向循环,制冷机做热泵运行,制冷机的蒸发器变为冷凝器,向循环风提供热量;记,ma为循环风的质量流量,kg/s;ca为空气比热;th为农作物人工气候室循环空调风回风口的风温,回风口布置在农作物人工气候室作物床的近地面部位;tc为循环空调风送风口的冷风(或热风)温度,送风口布置在农作物人工气候室上方靠近顶面;根据能量方程的得出Qk的计算式为:The energy balance of the crop artificial climate chamber is completed by the refrigeration and heating system and the air circulation system; the refrigeration and heating system uses the evaporator of the compression refrigerator and the circulating air circulating in the crop artificial climate chamber to exchange. Heat, provide cooling to the crop artificial climate chamber, balance the excess heat of solar radiation entering the crop artificial climate chamber, and keep the indoor air temperature within the allowable fluctuation range of the design temperature; at night, the crop artificial climate chamber dissipates heat to the outside, and the indoor temperature is In the downward trend, the refrigerant circulates in reverse, the refrigerator operates as a heat pump, and the evaporator of the refrigerator becomes a condenser to provide heat to the circulating air; note, m a is the mass flow of the circulating air, kg/s; c a is the specific heat of air; t h is the air temperature of the air return outlet of the circulating air conditioning air in the artificial climate chamber of crops, and the return air outlet is arranged near the ground of the crop bed in the artificial climate chamber of crops; t c is the cold air (or hot air) of the air supply air of the circulating air conditioning air temperature, the air supply port is arranged above the artificial climate chamber of crops and close to the top surface; according to the energy equation, the calculation formula of Q k is:

空调机调整农作物人工气候室气温提供的冷量Qk的计算式为:The calculation formula of the cooling capacity Q k provided by the air conditioner adjusting the room temperature of the artificial climate of crops is:

±Qk=maca(th-tc)=Q1+Q2+Q3+Q4-Qp1-Qp2-Qρ±Qm (30)±Q k =m a c a (t h -t c )=Q 1 +Q 2 +Q 3 +Q 4 -Q p1 -Q p2 -Q ρ ±Q m (30)

其中,ma为循环于农作物人工气候室和空调机蒸发器的循环风的质量流量,kg/s;ca为空气比热,th为农作物人工气候室循环空调风回风口的风温,回风口布置在农作物人工气候室作物床的近地面部位,tc为循环空调风送风口的冷风温度,送风口布置在农作物人工气候室上方靠近顶面;Among them, m a is the mass flow rate of the circulating air circulating in the crop artificial climate chamber and the evaporator of the air conditioner, kg/s; c a is the air specific heat, th h is the air temperature of the circulating air-conditioning air return port of the crop artificial climate chamber, The return air outlet is arranged near the ground of the crop bed in the crop artificial climate chamber, t c is the cold air temperature of the circulating air-conditioning air supply outlet, and the air supply outlet is arranged above the crop artificial climate chamber and close to the top surface;

当th>tc送冷风,当th<tc送热风,当th=tc时不送风;When t h >t c , supply cold air, when t h <t c , supply hot air, and when t h =t c , no air is supplied;

无遮光,且正午时,No shade, and at noon,

Qk,θ=0=85+6.94+1+2.5-11.7-2.07-6.84+0.41=75.24kW (30a)Q k, θ=0 =85+6.94+1+2.5-11.7-2.07-6.84+0.41=75.24kW (30a)

当使用遮光网遮光,且正午时When using a shading net to block light, and at noon

Qk,π,θ=0=43.8+26.1+1+2.5-6.01-7.77-3.96+0.41=56.07kW (30b)Q k, π, θ=0 = 43.8+26.1+1+2.5-6.01-7.77-3.96+0.41=56.07kW (30b)

当使用红外反射膜遮光,且正午时When using infrared reflective film to block light, and at noon

Figure BDA0002885871250000201
Figure BDA0002885871250000201

计算结果汇中表Calculation result summary table

Q<sub>1</sub>Q<sub>1</sub> Q<sub>p1</sub>Q<sub>p1</sub> Q<sub>p2,α</sub>Q<sub>p2,α</sub> Q<sub>2</sub>Q<sub>2</sub> Q<sub>3</sub>Q<sub>3</sub> Q<sub>ρ</sub>Q<sub>ρ</sub> Q<sub>4</sub>Q<sub>4</sub> Q<sub>m</sub>Q<sub>m</sub> Q<sub>k</sub>Q<sub>k</sub> 无遮光no shading 8585 -11.7-11.7 -2.07-2.07 6.946.94 1.01.0 -6.84-6.84 2.52.5 0.410.41 75.2475.24 遮光网shading net 43.843.8 -6.01-6.01 -7.77-7.77 26.126.1 1.01.0 -3.96-3.96 2.52.5 0.410.41 56.0756.07 遮光膜shading film 49.249.2 -10.7-10.7 -3.00-3.00 10.110.1 1.01.0 -6.04-6.04 2.52.5 0.410.41 43.4743.47

6H2O+6CO2+(光能2870kJ)→C6H12O6(180克)+6O2 (31a)6H 2 O+6CO 2 +(Light energy 2870kJ)→C 6 H 12 O 6 (180g)+6O 2 (31a)

EP+xE(H2O)+yE(CO2)=jE(CmHnOk)+iE(O2) (32)E P +xE(H 2 O)+yE(CO 2 )=jE(C m H n O k )+iE(O 2 ) (32)

室外日照能量Qout,D=Qout,0,dayA0=0.60×3600×8×100=1728000KJ;Outdoor sunshine energy Q out, D = Q out, 0, day A 0 =0.60×3600×8×100=1728000KJ;

日产生葡萄糖克数

Figure BDA0002885871250000202
Figure BDA0002885871250000203
Daily grams of glucose
Figure BDA0002885871250000202
Figure BDA0002885871250000203

在本说明书的描述中,参考术语“一个实施例/方式”、“一些实施例/方式”、“示例”、“具体示例”、或“一些示例”等的描述意指结合该实施例/方式或示例描述的具体特征、结构、材料或者特点包含于本申请的至少一个实施例/方式或示例中。在本说明书中,对上述术语的示意性表述不必须针对的是相同的实施例/方式或示例。而且,描述的具体特征、结构、材料或者特点可以在任一个或多个实施例/方式或示例中以合适的方式结合。此外,在不相互矛盾的情况下,本领域的技术人员可以将本说明书中描述的不同实施例/方式或示例以及不同实施例/方式或示例的特征进行结合和组合。In the description of this specification, references to the terms "one embodiment/mode", "some embodiments/modes", "example", "specific example", or "some examples", etc. are intended to be combined with the description of the embodiment/mode A particular feature, structure, material, or characteristic described by way of example or example is included in at least one embodiment/mode or example of the present application. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment/mode or example. Furthermore, the particular features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments/means or examples. Furthermore, those skilled in the art may combine and combine the different embodiments/modes or examples described in this specification and the features of the different embodiments/modes or examples without conflicting each other.

此外,术语“第一”、“第二”仅用于描述目的,而不能理解为指示或暗示相对重要性或者隐含指明所指示的技术特征的数量。由此,限定有“第一”、“第二”的特征可以明示或者隐含地包括至少一个该特征。在本申请的描述中,“多个”的含义是至少两个,例如两个,三个等,除非另有明确具体的限定。In addition, the terms "first" and "second" are only used for descriptive purposes, and should not be construed as indicating or implying relative importance or implying the number of indicated technical features. Thus, a feature delimited with "first", "second" may expressly or implicitly include at least one of that feature. In the description of the present application, "plurality" means at least two, such as two, three, etc., unless expressly and specifically defined otherwise.

本领域的技术人员应当理解,上述实施方式仅仅是为了清楚地说明本公开,而并非是对本公开的范围进行限定。对于所属领域的技术人员而言,在上述公开的基础上还可以做出其它变化或变型,并且这些变化或变型仍处于本公开的范围内。It should be understood by those skilled in the art that the above embodiments are only for clearly illustrating the present disclosure, but not for limiting the scope of the present disclosure. For those skilled in the art, other changes or modifications may also be made on the basis of the above disclosure, and these changes or modifications are still within the scope of the present disclosure.

Claims (10)

1.一种农作物人工气候室的补光方法,其特征在于,包括:1. a method for supplementing light in an artificial climate chamber for crops, is characterized in that, comprising: 建立农作物人工气候室的能量方程,Establish the energy equation of the artificial climate chamber for crops, 根据所述能量方程,调节照射入农作物人工气候室的光照,使得农作物人工气候室内部的农作物床的受照光合作用光谱能量与室外的农作物床的受照光合作用光谱能量相同,并使得所述农作物人工气候室内部处于预设温度内;According to the energy equation, the light irradiated into the crop artificial climate chamber is adjusted so that the photosynthetic spectral energy of the crop bed inside the crop artificial climate chamber is the same as the photosynthetic spectral energy of the outdoor crop bed, and the said The interior of the crop artificial climate chamber is within the preset temperature; 其中,所述的农作物人工气候室的单位时间能量方程为:Wherein, the unit time energy equation of the crop artificial climate chamber is:
Figure RE-FDA0002959254070000011
Figure RE-FDA0002959254070000011
所述能量方程中,正号为能量输入,负号为能量消耗,单位均为W;Q1为输入到农作物人工气候室内的太阳能量;Q2为补偿光灯消耗的电能量;Q3为农作物人工气候室内气流均匀化的附加风机消耗的电能量;Q4为玻璃罩对室内的传热量;Qp1、Qp2为农作物床吸收的太阳光和补偿光中的光合作用能量;Qρ是作物床反射到室外的辐射能量;
Figure RE-FDA0002959254070000012
为空调机循环风送给农作物人工气候室冷量或热量,当输入热量时为正号,输入冷量时为负号;±Qm为农作物人工气候室内的室内空气热容、作物床植株热容和根系土壤的热容吸热或放热量,吸热为负号,放热为正号。
In the described energy equation, the positive sign is the energy input, the negative sign is the energy consumption, and the unit is W; Q 1 is the solar energy input into the artificial climate room for crops; Q 2 is the electric energy consumed by the compensation light; Q 3 is The electric energy consumed by the additional fan for uniform air flow in the artificial climate of crops; Q 4 is the heat transfer from the glass cover to the room; Q p1 and Q p2 are the sunlight absorbed by the crop bed and the photosynthetic energy in the compensation light; Q ρ is radiant energy reflected from the crop bed outdoors;
Figure RE-FDA0002959254070000012
The circulating air of the air conditioner sends the cooling or heat to the artificial climate room for crops. When the heat input is positive, it is negative when the cooling is input; ±Q m is the indoor air heat capacity in the artificial climate room for the crops, and the heat of the crop bed plants. The heat capacity of the root soil is endothermic or exothermic, the endothermic is negative, and the exothermic is positive.
2.如权利要求1所述的农作物人工气候室的补光方法,其特征在于,当所述农作物人工气候室在未被遮挡时:2. the supplementary light method of crop artificial climate chamber as claimed in claim 1, is characterized in that, when described crop artificial climate chamber is not blocked: Q1=Gin,θA0=Gout,θτA0=(Gbcosθ+Gd)τA0 Q 1 =G in, θ A 0 =G out, θ τA 0 =(G b cosθ+G d )τA 0 其中,Gin,θ和Gout,θ分别为农作物人工气候室内部和外部的水平面受到太阳辐照强度,单位为W/m2,θ表示太阳光线的天顶角;τ为玻璃的平均透光率;A0为农作物人工气候室农作物床的面积,单位为m2;Gb为直射太阳辐射强度;Gd为散射太阳辐射强度;取Gb/Gd=6/4。Among them, G in, θ and G out, θ are the solar radiation intensity on the horizontal plane inside and outside the crop artificial climate chamber respectively, the unit is W/m 2 , θ is the zenith angle of sunlight; τ is the average transmittance of the glass light rate; A 0 is the area of the crop bed in the artificial climate chamber of crops, in m 2 ; G b is the direct solar radiation intensity; G d is the scattered solar radiation intensity; take G b /G d =6/4. 3.如权利要求2所述的农作物人工气候室的补光方法,其特征在于,当所述农作物人工气候室使用顶棚遮光网时:Q1记为Q1,π3. the supplementary light method of the artificial climate chamber of crops as claimed in claim 2, is characterized in that, when described artificial climate chamber of crops uses ceiling shading net: Q 1 is denoted as Q 1, π , Q1,π=[Gout,θ,b(1-πb)+Gd(1-πF21)]τA0 (4)Q 1, π = [G out, θ, b (1-π b )+G d (1-πF 21 )]τA 0 (4) 其中,Gout,θ,b为无遮光时太阳入射角为θ的太阳直射辐射能;πb为遮光网减少的直射辐射能的份额,等于作物床被遮光网遮挡的直射太阳照射面积份额与遮光网的遮光度π的乘积;当遮光网顶棚与作物床平行高度为Z,作物床宽度为xb,遮光网宽度为xz,从遮光网顶棚左端射到作物床的右端光线La的天顶角为θa,从遮光网顶棚左端射到作物床的左端光线Lb的天顶角为θb时;Among them, G out, θ, b is the direct solar radiant energy with the sun incident angle θ when there is no shading; π b is the share of the direct radiant energy reduced by the shading net, which is equal to the proportion of the direct sunlight irradiated area of the crop bed blocked by the shading net and the The product of the shading degree π of the shading net; when the parallel height of the shading net roof and the crop bed is Z, the width of the crop bed is x b , and the width of the shading net is x z , from the left end of the shading net roof to the right end of the crop bed The light La When the zenith angle is θ a , when the zenith angle of the light L b from the left end of the shading net roof to the left end of the crop bed is θ b ; 当θ≥θa时没有作用,There is no effect when θ≥θ a , πb=0(θ≥θa) (5a)π b = 0 (θ≥θ a ) (5a) 当θ<θa以后,随θ的继续减小,在作物床上出现遮光网的阴影面积,天顶角为θ的光线La在作物床上产生的阴影宽度用xπ表示,When θ < θ a , as θ continues to decrease, the shadow area of the shading net appears on the crop bed, and the width of the shadow produced by the light La with a zenith angle of θ on the crop bed is represented by x π , xπ=Z tanθa-Z tanθ=xa-xθ x π =Z tanθ a -Z tanθ = x a -x θ xa=Z tanθa,xθ=Z tanθ,xb=Z tanθbx a = Z tan θ a , x θ = Z tan θ , x b = Z tan θ b ;
Figure RE-FDA0002959254070000021
Figure RE-FDA0002959254070000021
当θb>θ后When θ b > θ πb=π (5c)π b = π (5c) 式(4)的散射辐射能Gd(1-πF21)中的πF21为遮光网在半球空间辐射中占有的份额,F21视觉系数为作物床平面所拦截的从遮光网顶棚面来的辐射份额;The πF 21 in the scattered radiation energy G d (1-πF 21 ) of the formula (4) is the share of the shading net in the hemispherical space radiation, and the F 21 visual coefficient is the intercepted by the crop bed plane from the shading net ceiling surface. radiation share; 根据太阳高度不同,天顶角θ不同,选择式(5a)或(5b)或(5c)代入式(4),计算有遮光时进入农作物人工气候室的太阳辐射能Q1,πAccording to the different height of the sun and the different zenith angle θ, choose formula (5a) or (5b) or (5c) and substitute it into formula (4) to calculate the solar radiation energy Q 1, π that enters the artificial climate chamber of crops when there is shading; 当θ=0时,When θ=0, Q1,π,θ=0=[Gout,θ,b(1-π)+Gd(1-πF21)]τA0 (θ=0)(4a)。Q 1 , π, θ=0 = [G out, θ, b (1−π)+G d (1−πF 21 )]τA 0 (θ=0) (4a).
4.如权利要求3所述的农作物人工气候室的补光方法,其特征在于,当采用铺设于农作物人工气候室顶层玻璃上面的红外反射半透明膜时,Q1记为
Figure RE-FDA0002959254070000025
可见光的遮光度为πp=0.1,可见光能量在太阳全辐射能中所占的份额为
Figure RE-FDA0002959254070000022
红外辐射反射膜的对波长λ≥780nm的红外光辐射遮光度为πh=0.9,波长λ≥780nm的红外光辐射能在太阳全辐射能中所占的份额为
Figure RE-FDA0002959254070000023
4. the supplementary light method of crop artificial climate chamber as claimed in claim 3, is characterized in that, when adopting the infrared reflection translucent film that is laid on the top glass of crop artificial climate chamber, Q 1 is denoted as
Figure RE-FDA0002959254070000025
The shading degree of visible light is π p = 0.1, and the share of visible light energy in the total solar radiation energy is
Figure RE-FDA0002959254070000022
The shading degree of infrared radiation reflection film to infrared light radiation with wavelength λ≥780nm is π h = 0.9, and the share of infrared light radiation energy with wavelength λ≥780nm in the total solar radiation energy is
Figure RE-FDA0002959254070000023
当采用顶层红外反射半透明膜时,太阳直射辐射能和散射辐射能分解为可见光和红外辐射两部分能量,并分别使用不同的遮光率πp和πh,使用红外反射半透明膜时,进入作物人工实验室的太阳辐射能为:When the top infrared reflective translucent film is used, the direct solar radiation energy and scattered radiant energy are decomposed into visible light and infrared radiation, and different shading rates π p and π h are used respectively. When the infrared reflective translucent film is used, entering The solar radiation energy of the crop artificial laboratory is:
Figure RE-FDA0002959254070000024
Figure RE-FDA0002959254070000031
Figure RE-FDA0002959254070000024
Figure RE-FDA0002959254070000031
式(6)按可见光部和红外辐射整理,得:Formula (6) is arranged according to the visible light part and the infrared radiation, we get:
Figure RE-FDA0002959254070000032
Figure RE-FDA0002959254070000032
当正午θ=0时,cosθ=1,记πb,p=πp,πb,h=πh,所以式(7)化作(7a)或(7b):When θ=0 at noon, cosθ=1, denote π b, p = π p , π b, h = π h , so formula (7) becomes (7a) or (7b):
Figure RE-FDA0002959254070000033
Figure RE-FDA0002959254070000034
Figure RE-FDA0002959254070000033
Figure RE-FDA0002959254070000034
or
Figure RE-FDA0002959254070000035
Figure RE-FDA0002959254070000035
其中,可见光的入室能量为:Among them, the entering energy of visible light is:
Figure RE-FDA0002959254070000036
Figure RE-FDA0002959254070000036
太阳红外辐射的入室能量为:The incoming energy of solar infrared radiation is:
Figure RE-FDA0002959254070000037
Figure RE-FDA0002959254070000037
与无遮光方案相比,入室的太阳能量差值为:Compared with the no-shading scheme, the difference in solar energy entering the room is:
Figure RE-FDA0002959254070000038
Figure RE-FDA0002959254070000038
式(9)中,可见光减少量为:In formula (9), the amount of visible light reduction is:
Figure RE-FDA0002959254070000039
Figure RE-FDA0002959254070000039
远红外辐射能减少量:Far-infrared radiant energy reduction:
Figure RE-FDA00029592540700000310
Figure RE-FDA00029592540700000310
与遮光网方案相比,入室的太阳辐射能量差值为:Compared with the shading net scheme, the difference in solar radiation energy entering the room is:
Figure RE-FDA00029592540700000311
Figure RE-FDA00029592540700000311
遮光网方案的可见光偏少量为:The visible light partial amount of the shading net scheme is:
Figure RE-FDA00029592540700000312
Figure RE-FDA00029592540700000312
扣除绿光份额后,遮光网方案的作物光合作用辐射能偏少量为:After deducting the green light share, the partial amount of crop photosynthesis radiant energy in the shading net scheme is:
Figure RE-FDA00029592540700000313
Figure RE-FDA00029592540700000313
减少补光灯的电功率为:To reduce the electric power of the fill light is: ΔP2,π-ρ=ΔQπ,VLd (16)ΔP 2, π-ρ = ΔQ π, VLd (16) 但是远红外辐射能增加量:But far-infrared radiant energy increases by:
Figure RE-FDA0002959254070000041
Figure RE-FDA0002959254070000041
绿光辐射能比遮光网的增多量为:The increase of green radiant energy than the shading net is:
Figure RE-FDA0002959254070000042
Figure RE-FDA0002959254070000042
按空调机性能系数COP计算,红外反射遮光膜的方案比遮光网的方案节省电功率为:Calculated according to the COP of the performance coefficient of the air conditioner, the scheme of infrared reflective shading film saves electric power compared with the scheme of shading net as follows: ΔP2,π-p=ΔP2,π-p-(ΔQπ,IR-AQπ,ρ)/COP (19)。ΔP 2,π-p =ΔP 2,π-p -(ΔQ π,IR -AQ π,ρ )/COP (19).
5.如权利要求4所述的农作物人工气候室的补光方法,其特征在于,5. the supplementary light method of crop artificial climate chamber as claimed in claim 4, is characterized in that, 农作物床的作物从太阳光吸收的光合作用的能量Qp1为:The photosynthetic energy Q p1 absorbed by the crops of the crop bed from sunlight is:
Figure RE-FDA0002959254070000043
Figure RE-FDA0002959254070000043
其中,记
Figure RE-FDA0002959254070000044
为太阳光中可被植物吸收的光合作用的能量份额,αp为植物的对光合作用光谱辐射能的吸收率,ξ为光合作用从光能变成化学能的效率;
Among them, note
Figure RE-FDA0002959254070000044
is the energy share of photosynthesis that can be absorbed by plants in sunlight, α p is the absorption rate of photosynthesis spectral radiant energy by plants, and ξ is the efficiency of photosynthesis from light energy to chemical energy;
在正午,无遮光时:At noon, without shade:
Figure RE-FDA0002959254070000045
Figure RE-FDA0002959254070000045
在使用遮光网时:When using shade nets:
Figure RE-FDA0002959254070000046
Figure RE-FDA0002959254070000046
在使用红外反射遮光膜时:When using IR reflective shading film:
Figure RE-FDA0002959254070000047
Figure RE-FDA0002959254070000047
6.如权利要求5所述的农作物人工气候室的补光方法,其特征在于,能量方程的补偿光中的光合作用光谱能量Qp2为室外、内的可见光光谱段的能量差,在无遮光时:6. the supplementary light method of crop artificial climate chamber as claimed in claim 5 is characterized in that, the photosynthesis spectral energy Q p2 in the compensation light of the energy equation is the energy difference of the visible light spectrum section of outdoor, inside, in no shading. Time:
Figure RE-FDA0002959254070000048
Figure RE-FDA0002959254070000048
补光灯的功率为:The power of the fill light is:
Figure RE-FDA0002959254070000049
Figure RE-FDA0002959254070000049
其中,ηd为补偿光灯的电光转化效率;Wherein, η d is the electro-optical conversion efficiency of the compensation light lamp; 在无遮光且正午θ=0时的补偿光灯的能量Q2,θ=0、被作物吸收的光合作用能量记作Qp2,θ=0When there is no shading and θ=0 at noon, the energy Q 2 of the compensation light, θ=0 , the photosynthetic energy absorbed by the crop is recorded as Q p2, θ=0 ;
Figure RE-FDA00029592540700000410
Figure RE-FDA00029592540700000410
Figure RE-FDA0002959254070000051
Figure RE-FDA0002959254070000051
在采用顶棚遮光网θ=0时,Q1采用式(4)的Q1,π计算,Q2记作Q2,π,Qp2记作Qp2,π,则:When using the ceiling shading net θ=0, Q 1 is calculated using Q 1, π of formula (4), Q 2 is denoted as Q 2, π , and Q p2 is denoted as Q p2, π , then:
Figure RE-FDA0002959254070000052
Figure RE-FDA0002959254070000052
Qp2,π=(Gout,θ,bπb+GdπF21)τA0 (23b)Q p2, π = (G out, θ, b π b +G d πF 21 )τA 0 (23b) 在采用红外反射遮光膜时,且正午时的补偿光功率
Figure RE-FDA0002959254070000053
和被农作物吸收的能量
Figure RE-FDA0002959254070000054
When using infrared reflective shading film, and the compensation optical power at noon
Figure RE-FDA0002959254070000053
and energy absorbed by crops
Figure RE-FDA0002959254070000054
Figure RE-FDA0002959254070000055
Figure RE-FDA0002959254070000055
Figure RE-FDA0002959254070000056
Figure RE-FDA0002959254070000056
其中,Qout,0取100。Among them, Q out, 0 is 100.
7.如权利要求6所述的农作物人工气候室的补光方法,其特征在于,农作物人工气候室反射的辐射能Qρ为:7. the light supplement method of crop artificial climate chamber as claimed in claim 6, is characterized in that, the radiant energy Q ρ of crop artificial climate chamber reflection is:
Figure RE-FDA0002959254070000057
Figure RE-FDA0002959254070000057
其中,
Figure RE-FDA0002959254070000058
in,
Figure RE-FDA0002959254070000058
当无遮光θ=0时的绿光反射量,记作Qρ,θ=0When there is no shading θ=0, the green light reflection amount is denoted as Q ρ, θ=0 ;
Figure RE-FDA0002959254070000059
Figure RE-FDA0002959254070000059
当顶层采用遮光网遮光且θ=0,遮光网的遮光度π=0.6时的绿光反射量,记作Qρ,θ=0,π=0.6When the top layer adopts a shading net to shield the light and θ=0, the green light reflection amount when the shading degree of the shading net is π=0.6 is recorded as Q ρ, θ=0, π=0.6 ;
Figure RE-FDA00029592540700000510
Figure RE-FDA00029592540700000510
当采用红外反射遮光膜时,可见光遮光度为πp=0.1,红外遮光度为πp,h,θ=0时的绿光反射量,记作Qρ,θ=0,π=0.1When the infrared reflective shading film is used, the visible light shading degree is π p = 0.1, the infrared shading degree is π p, h , the green light reflection amount when θ = 0 is denoted as Q ρ, θ = 0, π = 0.1 ,
Figure RE-FDA00029592540700000511
Figure RE-FDA00029592540700000511
其中at取0.6,ad取0.4,Gout=Gb+Gdwhere at is 0.6, a d is 0.4, and G out =G b +G d .
8.如权利要求7所述的农作物人工气候室的补光方法,其特征在于,所述能量方程中的Q4为玻璃罩对室内的传热量:8. the supplementary light method of crop artificial climate chamber as claimed in claim 7 , is characterized in that, Q in described energy equation is glass cover to indoor heat transfer: 在白天:In the daytime: Q4=0.5Gout(1-τ-ρ)A0=0.5(Gbcosθ+Gd)αA0 (26)Q 4 =0.5G out (1-τ-ρ)A 0 =0.5(G b cosθ+G d )αA 0 (26) 当正午太阳天顶角θ=0°时,When the noon sun zenith angle θ=0°, Q4=0.5(Gb+Gd)(1-τ)A0=0.5Gout(1-τ-ρ)A0(26a)Q 4 =0.5(G b +G d )(1-τ)A 0 =0.5G out (1-τ-ρ)A 0 (26a) 夜晚没有太阳辐射,则There is no solar radiation at night, then Q4=KA(Tg1-T)=KA(Tout-Tg2) (27)Q 4 =KA(T g1 -T)=KA(T out -T g2 ) (27) 式中K为玻璃壁对空气的平均传热系数,A为玻璃房的玻璃壁面积,Tg1、Tg2分别为室内、外侧玻璃温度,T、Tout分别为室内、外空气温度。In the formula, K is the average heat transfer coefficient of the glass wall to the air, A is the glass wall area of the glass room, T g1 and T g2 are the indoor and outer glass temperatures, respectively, and T and T out are the indoor and outdoor air temperatures, respectively. 9.如权利要求8所述的农作物人工气候室的补光方法,其特征在于,农作物人工气候室的热容吸热或放热量Qm9. the supplementary light method of crop artificial climate chamber as claimed in claim 8 is characterized in that, the heat capacity of crop artificial climate chamber absorbs heat or releases heat Q m : Qm=MacadTa/dt+MfcfdTf/dt+MscsdTs/dt (28)Q m =M a c a dT a /dt+M f c f dT f /dt+M s c s dT s /dt (28) 式中的Ma、Mf、Ms分别为农作物人工气候室内的空气、作物床秸秆、作物床的植物根系土壤的质量,Ma≈Mf<<Ms,所以Mscs的热容是农作物人工气候室的热沉,其温度变化不敏感,当植物根系土壤温度达到设定值后,温度控制只要保留空气和作物床植株的热容波动项;dTa/dt、dTf/dt、dTs/dt分别为室内空气平均气温、作物床秸秆平均温度、作物床的植物根系土壤平均温度的变化速率;In the formula , Ma , M f , and Ms s are the quality of the air, crop bed straw , and plant root soil of the crop bed, respectively . The capacity is the heat sink of the artificial climate chamber of crops, and its temperature change is not sensitive. When the soil temperature of the plant root reaches the set value, the temperature control only needs to keep the heat capacity fluctuation terms of the air and the crop bed plants; dT a /dt, dT f / dt and dT s /dt are the rate of change of the average indoor air temperature, the average temperature of the crop bed straw, and the average temperature of the plant root soil in the crop bed; 当农作物人工气候室的室内空气温度控制要求30分钟内允许波动1℃,植株和空气的热容基本相同,Qm通过下式获得:When the indoor air temperature control of the artificial climate room for crops requires a fluctuation of 1°C within 30 minutes, the heat capacity of the plant and the air is basically the same, and Q m is obtained by the following formula: Qm=(Mafcaf)dTa/dt (29)Q m =(M af c af )dT a /dt (29) 其中Mafcaf=Maca+Mfcfwhere M af c af = M a c a + M f c f . 10.如权利要求9所述的农作物人工气候室的补光方法,其特征在于,空调机循环风送给农作物人工气候室冷量或冷量±Qk10. the light supplement method of the artificial climate chamber for crops as claimed in claim 9, it is characterized in that, the circulating air of the air conditioner is sent to the artificial climate chamber of crops refrigerating capacity or cooling capacity ± Q k : ±Qk=maca(th-tc)=Q1+Q2+Q3+Q4-Qp1-Qp2-Qρ±Qm(30)±Q k =m a c a (t h -t c )=Q 1 +Q 2 +Q 3 +Q 4 -Q p1 -Q p2 -Q ρ ±Q m (30) 其中,ma为循环风的质量流量,kg/s;ca为空气比热;th为农作物人工气候室循环空调风进入换热器前的来自农作物人工气候室的回风温度或是回风与新风混合的风温,回风口布置在农作物人工气候室作物床的近地面部位;tc为循环空调风在送风口进入农作物人工气候室前的气温,送风口布置在农作物人工气候室上方靠近顶面;Among them, m a is the mass flow rate of the circulating air, kg/s; c a is the air specific heat; t h is the return air temperature or the return air from the crop artificial climate chamber before the circulating air-conditioning air enters the heat exchanger. The air temperature mixed with the fresh air, the return air outlet is arranged near the ground of the crop bed in the crop artificial climate chamber; t c is the temperature of the circulating air-conditioning air before the air supply port enters the crop artificial climate chamber, and the air supply port is arranged above the crop artificial climate chamber near the top; 当th>tc送冷风,当th<tc送热风。When th h > t c , send cold air, when th < t c , send hot air.
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