/ 1、离网系统的价值

通过长期总结来看，离网系统主要基于以下几个出发点：

（1）没有办法使用市电（电网）的地方 ，如山上、船上、车上、野外等。这是最典型的离网系统需求；80%以上的使用者都是因为不方便用市电，想通过离网系统实现供电。

（2）有市电、但经常出现不规则停电的地区 。当停电的时候，可通过光伏离网系统继续供应负载，满足持续用电需求。

（3）有市电、但希望通过离网系统降低电费 。离网系统不光可以通过光伏组件来充蓄电池，也可以在费率低的时候通过设置市电给蓄电池充电，然后在费率高的时候通过蓄电池放电来供应负载。

/ 2、典型离网系统组成

离网系统图

上图是一个典型的离网系统的组成图。需要注意这几点：

（1）离网系统指的是系统输出不需要像并网光伏系统一样接入市电电网。离网系统的输出就是供应负载的。

（2）离网系统提供V-F源，它就相当于一个电网的角色。

（3）离网系统中的主要设备有：光伏组件、离网逆变器、蓄电池组、汇流装置、配电箱、用电负载。

（4）最精简的离网系统可以只包含2个部分：离网逆变器、蓄电池组。

/3、离网系统设计过程

（1）确认需求

做离网系统是个“量体裁衣”的过程，因为多数情况下不同用户需要带的负载都一样，用电时长也不一样。正确的方式，是先确认需求：即将要带哪些负载？负载有多大？一天当中使用多长时间？然后推算出需要建多大的系统。例如，华北地区某客户需求做一套离网电站，主要负载是1台3500W的鼓风机，每天用电时长3小时，备电需求1天即可。由这些信息可知，负载的功率为3.5KW，1天的耗电量为10.5kWh。

（2）离网机选型

早期离网系统控制部分由MPPT控制器+DC/AC转换器来执行，随着技术发展，目前主流厂家都提倡使用控制逆变一体机，一台设备就可同时实现功能，例如古瑞瓦特的SPF ES系列离网逆变器。

确认好需求后，就来选择合适的离网逆变器。所选择的离网机的输出，必须能覆盖负载的额定功率，且尽量留一些裕量，为的是系统更可靠。以上图中的负载为例，额定功率3.5kW，可以选择SPF 5000 ES离网机，输出功率为5kW，可以满足该负载的供电。

在覆盖负载功率的前提下，需要多少台逆变器，就要看备电需求了，也就是所谓的“连续阴雨天数”。因为离网系统中的电是组件和离网机合作发的，如果备电需求较大，1台离网机和它所匹配的组件可能发不出来，所以就需要倍加。

（3）光伏组件的选择

只要是光伏系统，能量来源都是光伏组件（当然，离网系统还有市电作为输入的情况）。而选定的离网机有其设定的可接受的组件容量，此处可以直接根据离网机的规格参数来配组件。采用目前主流的182组件550Wp*8块，额定功率4.4kWp，每日平均发电量约16kWh。也可以顶格配甚至超配一点，需要根据具体需求做匹配。

组件的串并方式其实跟并网逆变器的原理是一样的，离网机的组串有最大允许接入电压值，可根据所选组件的参数进行串接。SPF 5000ES离网机的最大PV输入电压为450V，MPPT电压范围为120V~430V，若选用550Wp组件，一般开路电压约在49V，可直接按8块1串，接入离网机的PV输入端口。

（4）蓄电池选择

蓄电池是离网系统区别于并网系统的一大特点，它是系统的缓冲调节地带，否则系统会变成一个孤岛。

在选择蓄电池时，还是依据用户的用电需求来做。以上文举例来看，客户有一个10.5kWh的备电需求，就是说，如果没有光照的情况下，蓄电池需要通过离网机释放出10.5度电，才能满足负载供应。

但是，不论铅酸类电池还是锂离子类电池，都有一个放电深度（DoD=Depth of Discharge）的概念或特性，是必须要考虑进去的。就是说，存入蓄电池中的电，不能每次都100%完全释放完，只能释放其中的一部分，否则会对蓄电池造成损害致使电池过早失效。

一般的铅酸类电池放电深度在60%左右，而锂电池可以达到90%。在选择蓄电池组容量时，放电深度也影响到了蓄电池组总的容量大小。还是以上面举例，选择铅酸电池，10.5度电按60%的放电深度来计算，需要配置总共10.5kWh÷0.6=17.5kWh的蓄电池组，这些蓄电池好比要一个容器，将系统所发出的电存储起来，在负载需要时再放出。

不需要那么复杂的计算单个蓄电池的容量或规格，5kW离网机要求配置的蓄电池应在200Ah规格以上，知道了这个，只需通过数量调整，配出相同或接近的总蓄电池容量即可。

1. Value of off-grid systems

From a long-term summary, off-grid systems are mainly based on the following starting points:

(1) There is no way to use the electricity (grid), such as mountains, boats, cars, the field and so on. This is the most typical off-grid system requirement; More than 80% of users are not convenient to use the mains, want to achieve power supply through the off-grid system.

(2) there is mains electricity, but often irregular power outage areas. In case of power failure, the photovoltaic off-grid system can continue to supply the load, to meet the continuous demand.

(3) Have mains power, but want to reduce the electricity bill through off-grid system. The off-grid system can not only charge the battery by photovoltaic modules, but also charge the battery by setting mains power when the rate is low, and then supply the load by discharging the battery when the rate is high.

/2. Composition of typical off-grid system

The picture

Off-grid system diagram

The diagram above shows the composition of a typical off-grid system. These points should be noted:

(1) The off-grid system refers to the system output does not need to be connected to the mains power grid like the grid-connected photovoltaic system. The output of the off-grid system is the supply load.

(2) The off-grid system provides a V-F source, which acts as a power grid.

(3) The main equipment in the off-grid system includes: photovoltaic modules, off-grid inverters, battery packs, confluence devices, distribution boxes and electrical loads.

(4) The most streamlined off-grid system can only contain two parts: off-grid inverter, battery pack.

/3. Off-grid system design process

(1) Confirm requirements

Making an off-grid system is a "discretionary" process, because in most cases different users need to carry the same load, and the duration of electricity is different. The right way is to first identify the requirements: what loads are going to be carried? How big is the load? How long is it used in a day? And then figure out how big the system needs to be. For example, a customer in North China needs to build a set of off-grid power station. The main load is a 3500W blower, which uses electricity for 3 hours every day and can provide backup power for 1 day. Based on this information, the power of the load is 3.5KW and the power consumption is 10.5kWh per day.

(2) Off-grid machine selection

Early off-grid system control part by MPPT controller +DC/AC converter to perform, with the development of technology, the current mainstream manufacturers are advocating the use of control inverter integrated machine, one device can achieve functions at the same time, such as Gurewatt's SPF ES series off-grid inverter.

After confirming the demand, we will choose the appropriate off-grid inverter. The output of the selected off-grid machine must be able to cover the rated power of the load, and try to leave some margin, in order to make the system more reliable. The load in the above figure is used as an example. The rated power is 3.5kW. The SPF 5000 ES off-grid unit can be selected, and the output power is 5kW.

The picture

Under the premise of covering the load power, how many inverters are needed depends on the backup power demand, which is the so-called "continuous rainy days". Because the power in the off-grid system is generated jointly by the components and the off-grid machine, if the backup power demand is large, one off-grid machine and its matched components may not be generated, so it needs to be multiplied.

(3) Selection of photovoltaic modules

As long as it is a photovoltaic system, the energy source is photovoltaic modules (of course, off-grid systems and mains power as input). The selected off-grid machine has its set acceptable component capacity, here can be directly according to the off-grid machine specifications to match the components. Adopt the current mainstream 182 assembly 550Wp*8 blocks, rated power 4.4kWp, daily average generation of about 16kWh. It can also be matched to the top or even to the top, which needs to be matched according to specific needs.

The combination of components is actually the same as the principle of grid-connected inverter. The group string of off-grid machine has the maximum allowable access voltage value, which can be connected according to the parameters of the selected components. The maximum PV input voltage of the SPF 5000ES off-grid machine is 450V, and the MPPT voltage ranges from 120V to 430V. If 550Wp components are used, the general open-circuit voltage is about 49V. You can directly press 8 blocks in a series to connect to the PV input port of the off-grid machine.

(4) Battery selection

The battery is a major feature of the off-grid system that is different from the grid-connected system. It is the buffer zone of the system, otherwise the system will become an island.

The picture

In the choice of battery, or according to the user's demand for electricity to do. For example, the customer has a 10.5kWh backup power requirement, which means that the battery needs to release 10.5kwh of power through the off-grid machine to meet the load when there is no light.

However, both lead-acid batteries and lithium-ion batteries have a concept or characteristic of Depth of Discharge (DoD=Depth of Discharge), which must be taken into account. That is to say, the electricity stored in the battery cannot be released 100% each time. Only a part of it can be released. Otherwise, the battery will be damaged and the battery will fail prematurely.

Typical lead-acid batteries discharge to a depth of around 60%, while lithium batteries can discharge to a depth of 90%. When selecting the battery capacity, the discharge depth also affects the total capacity of the battery. Take the above example again, choose the lead-acid battery, 10.5kWh of electricity is calculated according to 60% discharge depth, need to configure a total 10.5kwh / 0.6=17.5kWh battery set, these batteries are like a container, the system to store the electricity, when the load needs to release.

Do not need so complex to calculate the capacity or specifications of a single battery, 5kW off-grid machine requirements configuration of the battery should be more than 200Ah specifications, know this, just through the number of adjustment, with the same or close to the total battery capacity.