Photovoltaic heating system and matching method of heating element thereof
阅读说明:本技术 一种光伏发热系统及其发热元件的匹配方法 (Photovoltaic heating system and matching method of heating element thereof ) 是由 窦宗礼 冯成进 于 2021-01-05 设计创作,主要内容包括:本申请公开了一种光伏发热系统及其发热元件的匹配方法,其中,所述系统包括发热元件、光伏元件,所述发热元件的阻值R与光伏元件的最大输出功率P-(max)、最大输出功率P-(max)对应的工作电压V-(mp)之间满足以下公式:其中,a作为影响系数且1.05≤a≤1.40。通过该方案,在提高输出功率的基础上,提供一种通用性强的光伏发热系统。(The application discloses photovoltaic heating system and matching method of heating element thereof, wherein the system comprises the heating element and the photovoltaic element, and the resistance value R of the heating element and the maximum output power P of the photovoltaic element max Maximum output power P max Corresponding operating voltage V mp Satisfies the following formula: wherein a is used as an influence coefficient and is more than or equal to 1.05 and less than or equal to 1.40. Through the scheme, the photovoltaic heating system with strong universality is provided on the basis of improving the output power.)
1. A photovoltaic heating system comprises a heating element and a photovoltaic element, and is characterized in that the resistance value R of the heating elementTMaximum output power P of photovoltaic elementmaxMaximum output power PmaxCorresponding operating voltage VmpSatisfies the following formula:
wherein a is used as an influence coefficient and is more than or equal to 1.05 and less than or equal to 1.40.
2. The system of claim 1, wherein a is 1.178.
3. The system of claim 1 wherein a is 1.2962.
4. The system of claim 1, wherein a is inversely related to the illumination intensity of the installation area of the photovoltaic heating system.
5. The system of claim 1, wherein the photovoltaic element is comprised of at least one photovoltaic panel.
6. System according to claim 5, characterized in that the maximum power P of the photovoltaic element is determined according to the connection relationship between the photovoltaic panelsmax。
7. The system of claim 1, wherein the heating element is comprised of at least one heating element.
8. A heating element matching method of a photovoltaic heating system, the photovoltaic heating system comprising: heating element, photovoltaic element characterized in that, the method comprises:
obtaining the maximum output power P of the photovoltaic elementmaxAnd the maximum output power PmaxCorresponding operating voltage Vmp;
The resistance value R of the heating element is calculated according to the following formulaT:
a is used as an influence coefficient and is more than or equal to 1.05 and less than or equal to 1.40;
wherein a is obtained by:
dividing an area in which the photovoltaic heating system is preset into a plurality of areas to be detected according to a preset electronic map;
according to a corresponding preset period, acquiring output power of a plurality of test photovoltaic heating systems arranged in each region to be tested; the resistance values of the test heating elements of the test photovoltaic heating systems in the regions to be tested are different and are set according to corresponding preset rules;
determining a target load resistance value of the test photovoltaic heating system according to the obtained output power of each test photovoltaic heating system and the resistance value of the corresponding test heating element; and
calculating theoretical load resistance values of the test photovoltaic elements of the test photovoltaic heating systems according to a preset rule;
and determining the value of a according to each target load resistance value and the corresponding theoretical load resistance value.
9. The method according to claim 5, wherein the determining a target load resistance value of each test photovoltaic heating system according to the obtained output power of each test photovoltaic heating system and the corresponding load resistance value of the test heating element specifically comprises:
determining a load resistance value corresponding to the maximum output power of the test photovoltaic heating system according to the obtained output power of the test photovoltaic heating system, and taking the load resistance value as an undetermined optimal resistance value of the test photovoltaic heating system;
calculating the target load resistance value according to the following formula:
wherein R is2For the undetermined optimal resistance value, R1And R3Is closest to the resistance value of each test heating element2Resistance value of said W1Is the said R1Corresponding output power, W2Is the said R2Corresponding output power, W3Is the said R3The corresponding output power.
Technical Field
The application relates to the technical field of photovoltaics, in particular to a photovoltaic heating system and a matching method of heating elements of the photovoltaic heating system.
Background
With the continuous deepening of the global warming problem, green energy is more and more popular in various industries, and photovoltaic energy is the most common and widely applied in the green energy. Photovoltaic energy is widely used in various fields, and particularly, a great market potential exists in a heating system (such as a photovoltaic water heater).
In a photovoltaic heating system, the output power of a photovoltaic element of the system is particularly important, and the output power of the photovoltaic element is an important index of the working efficiency of the photovoltaic heating system. As known to those skilled in the art, the power output of the power supply is maximized when the external resistance is equal to the internal resistance. That is, the output power of the photovoltaic element of the photovoltaic heating system is related to the load resistance of the heating element, and the output power of the photovoltaic element is the maximum when the load resistance of the heating element is equal to the resistance of the photovoltaic element.
In the actual use process, the electromotive force energy of the photovoltaic element can be changed due to the influence of the illumination intensity and the illumination duration, so that the output power of the photovoltaic element is unstable and cannot reach the best state. In order to better guarantee the output power of the photovoltaic element, the best choice is: the load resistance of the heating element changes as the electromotive energy of the photovoltaic element changes. However, no corresponding equipment or scheme is available in the prior art, and the scheme can be implemented.
Therefore, it is an urgent technical problem to provide a system having versatility while improving the output power of the photovoltaic heating system.
Disclosure of Invention
The embodiment of the specification provides a photovoltaic heating system and a matching method of a heating element thereof, which are used for solving the following problems in the prior art: the prior art can not provide a photovoltaic heating system of commonality to furthest's improvement photovoltaic heating system's output.
The embodiment of the specification adopts the following technical scheme:
a photovoltaic heating system comprises a heating element and a photovoltaic element, wherein the resistance value R of the heating elementTMaximum output power P of photovoltaic elementmaxMaximum output power PmaxCorresponding operating voltage VmpSatisfies the following formula:
wherein a is an influence coefficient and 1.05≤a≤1.40。
In some embodiments of the present application, a is 1.178.
In some embodiments of the present application, the value of a is 1.2962.
In some embodiments of the present application, the value of a and the illumination intensity of the region to be measured are in a negative correlation relationship.
In some embodiments of the present application, the photovoltaic element is comprised of at least one photovoltaic panel.
In some embodiments of the present application, the maximum power P of the photovoltaic element is determined according to the connection relationship between the photovoltaic panelsmax。
In some embodiments of the present application, the heating element is comprised of at least one heating element. A heating element matching method of a photovoltaic heating system, the photovoltaic heating system comprising: a heating element, a photovoltaic element; resistance value R of the heating elementTMaximum output power P of photovoltaic elementmaxMaximum output power PmaxCorresponding operating voltage VmpSatisfies the following formula:
wherein a is used as an influence coefficient and is more than or equal to 1.05 and less than or equal to 1.40;
the method for calculating the value of the a comprises the following steps:
dividing an area in which the photovoltaic heating system is preset into a plurality of areas to be detected according to a preset electronic map;
according to a corresponding preset period, acquiring output power of a plurality of test photovoltaic heating systems arranged in each region to be tested; the resistance values of the test heating elements of the test photovoltaic heating systems in the regions to be tested are different and are set according to corresponding preset rules;
determining a target load resistance value of the test photovoltaic heating system according to the obtained output power of each test photovoltaic heating system and the resistance value of the corresponding test heating element;
calculating theoretical load resistance values of the test photovoltaic elements of the test photovoltaic heating systems according to a preset rule;
and determining the value of a according to each target load resistance value and the corresponding theoretical load resistance value.
In some embodiments of the present application, determining a target load resistance value of each test photovoltaic heating system according to the obtained output power of each test photovoltaic heating system and a load resistance value of the corresponding test heating element specifically includes:
determining a load resistance value corresponding to the maximum output power of the test photovoltaic heating system according to the obtained output power of the test photovoltaic heating system, and taking the load resistance value as an undetermined optimal resistance value of the test photovoltaic heating system;
calculating the target load resistance value according to the following formula:
wherein R is2For the undetermined optimal resistance value, R1And R3Is closest to the resistance value of each test heating element2Resistance value of said W1Is the said R1Corresponding output power, W2Is the said R2Corresponding output power, W3Is the said R3The corresponding output power.
The embodiment of the specification adopts at least one technical scheme which can achieve the following beneficial effects: on the basis of improving the output power of the system, a universal photovoltaic heating system is provided, so that the system is suitable for different environments to the greatest extent.
Drawings
The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:
fig. 1 is a schematic structural diagram of a photovoltaic heating system provided in an embodiment of the present disclosure;
fig. 2 is a schematic flow chart of a photovoltaic heating system provided in an embodiment of the present specification;
fig. 3 is a schematic view of a photovoltaic heating system provided in an embodiment of the present disclosure
Fig. 4 is another schematic view of a photovoltaic heating system provided in an embodiment of the present disclosure;
fig. 5 is a schematic view of a photovoltaic heating system provided in an embodiment of the present disclosure;
fig. 6 is another schematic view of a photovoltaic heating system provided in an embodiment of the present description;
fig. 7 is a schematic view of a photovoltaic heating system provided in an embodiment of the present disclosure;
fig. 8 is another schematic view of a photovoltaic heating system provided in an embodiment of the present description.
Detailed Description
In order to make the objects, technical solutions and advantages of the present disclosure more apparent, the technical solutions of the present disclosure will be clearly and completely described below with reference to the specific embodiments of the present disclosure and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all of the embodiments. All other embodiments obtained by a person skilled in the art without making any inventive step based on the embodiments in the description belong to the protection scope of the present application.
The technical solutions provided by the embodiments of the present application are described in detail below with reference to the accompanying drawings.
Fig. 1 is a schematic structural diagram of a photovoltaic heat generation system provided in an embodiment of the present specification, and as shown in fig. 1, a photovoltaic heat generation system 100 provided in an embodiment of the present specification may include: heating element 110, photovoltaic element 120. The heating element 110 is connected to the photovoltaic element 120, the heating element 110 is configured to convert solar energy into electric energy, and supply power to the heating element 110 according to the electric energy obtained by conversion, and the heating element 110 is configured to convert the electric energy into heat energy.
Resistance value R of the heating element 110TMaximum output with photovoltaic heating systemOutput power PmaxMaximum output power PmaxCorresponding operating voltage VmpSatisfies the following formula:
wherein a is an influence coefficient and is more than or equal to 1.05 and less than or equal to 1.40.
In some embodiments of the present description, the photovoltaic element 120 described above may be composed of several photovoltaic panels.
Further, in the case that the photovoltaic element 120 is composed of two or more photovoltaic panels, in the embodiment of the present specification, it is necessary to first obtain the connection relationship between the photovoltaic panels, and determine the maximum power P of the photovoltaic element 120 according to the connection relationship between the photovoltaic panelsmax. Wherein, the connection relation between each photovoltaic board can include: series connection and parallel connection.
When the connection relationship between the photovoltaic panels in the photovoltaic element 120 is parallel connection, the maximum output power P of the photovoltaic element 120maxThe sum of the maximum output power of each photovoltaic panel. It should be noted that V is required to be satisfied between the photovoltaic panels connected in parallelmpThe same requirements apply. For example, the photovoltaic element 120 is composed of a photovoltaic panel a and a photovoltaic panel B connected in parallel, wherein V of the photovoltaic panel ampAnd V of photovoltaic panel BmpSimilarly, when the maximum output power of the photovoltaic panel a is 300W and the maximum output power of the photovoltaic panel B is 400W, the maximum output power P of the photovoltaic element 120 ismax=300+400=700W。
When the connection relationship between the photovoltaic panels in the photovoltaic element 120 is series connection, the maximum output power P of the photovoltaic element 120maxAnd is also the sum of the maximum powers of the photovoltaic panels. It should be noted that the requirements between the photovoltaic panels connected in series are satisfiedThe same value is required. For example, photovoltaic element 120 is composed of a series connection of photovoltaic panel C and photovoltaic panel D, of which photovoltaic panel C hasOf the value of (D) and of the photovoltaic panel DThe maximum output power of the photovoltaic panel C is 350W, the maximum output power of the photovoltaic panel D is 400W, and then the maximum output power P of the photovoltaic elementmax=350+400=750W。
Furthermore, in the case of both series connection and parallel connection between the photovoltaic panels of the photovoltaic element 120, the photovoltaic panels connected in parallel satisfy VmpIn the same way, the photovoltaic panels in series satisfyThe values of (a) are the same. For example, the photovoltaic element 120 is composed of a photovoltaic panel a, a photovoltaic panel B, and a photovoltaic panel C; the photovoltaic panel A and the photovoltaic panel B are connected in parallel to form a parallel module and then are connected in series with the photovoltaic panel C, so that the V of the photovoltaic panel AmpAnd V of photovoltaic panel BmpThe same; meanwhile, the photovoltaic panel A and the photovoltaic panel B are connected in parallel to form a parallel moduleWith photovoltaic panels CThe same is true.
In some embodiments of the present description, the heating element 110 is composed of at least one heating element. Specifically, the resistance value R of the heat generating element may be determinedTAnd determining the number and the specification of the heating elements in the heating element.
It should be noted that the heating element mentioned herein may be a heating tube, a heating plate, an electric heating wire, or other devices having a heating function, and the specific form of the heating element is not particularly limited in the embodiments of the present application, and may be adjusted according to actual situations.
In some embodiments of the present specification, as shown in fig. 2, the value of a may be implemented according to the following method:
s201, dividing an area in which the photovoltaic heating system is preset into a plurality of areas to be detected according to a preset electronic map.
In this application specification, can divide the region that sets up photovoltaic heating system according to average illumination intensity to obtain a plurality of regions that await measuring.
For example, the average illumination intensity is within a corresponding preset range, and the area adjacent to the geographical position is divided into an area to be measured. That is, the illumination intensity in each region to be measured can be regarded as the same.
The above-mentioned region where the photovoltaic heating system is disposed may refer to a region where the photovoltaic heating system can be installed or where the photovoltaic heating system needs to be installed, and is not particularly limited in the embodiment of the present specification. For example, a photovoltaic heating system can be installed in all parts of the world, and the world can be used as the above-mentioned region where the photovoltaic heating system is installed.
S202, acquiring output power of a plurality of test photovoltaic heating systems arranged in each region to be tested according to a corresponding preset period.
The resistance values of the test heating elements of the test photovoltaic heating systems arranged in the regions to be tested are different and can be set according to corresponding preset rules. Test photovoltaic heating system includes: a test heating element and a test photovoltaic element.
In the embodiment of the specification, each region to be tested is provided with a plurality of test photovoltaic heating systems, and relevant parameters of the plurality of test photovoltaic heating systems are stored in corresponding storage devices. The relevant parameters for testing the photovoltaic heating system mentioned herein may include: and testing the resistance value of the heating element, testing the maximum output power of the photovoltaic element and the like.
The preset period may be divided according to a time parameter, for example, 30 minutes is used as a time interval, and 30 minutes is a preset period. It should be noted that, in the embodiment of the present specification, the preset period is not specifically limited, and may be adjusted accordingly according to actual situations.
The server can obtain the output power of each testing photovoltaic heating system in the area to be tested according to a preset period. It should be noted that, here, the output power corresponding to the time when the next preset period is entered may be mentioned, or the output power may be obtained multiple times in the preset period according to the corresponding time interval, and an average value is obtained as the output power corresponding to the preset period, which is not limited in the embodiment of the present specification.
Furthermore, in the same area and at the same time, the collected illumination intensity, air temperature and humidity of the area are the same. Therefore, in the embodiment of the present specification, the working voltage V of each test photovoltaic heating system needs to be collected according to a preset period, the collected data is shown in table 1, and table 1 is used to represent measured data of the working voltage variation of the test photovoltaic element at different time periods and different loads.
TABLE 1
Furthermore, the working voltages under different loads can be measured through table 1, and the corresponding output power W is calculated according to the following formula:
in the embodiment of the present specification, table 2 may be composed according to the calculated corresponding output power W, where table 2 is used to indicate the output power variation of the test photovoltaic element under different time periods and different loads.
TABLE 2
And S203, determining a target load resistance value in the preset period according to the acquired output power of each test photovoltaic heating system and the resistance value of the corresponding test heating element.
Specifically, according to the obtained output power of the photovoltaic heating system to be tested, determining a load resistance value corresponding to the maximum output power of the photovoltaic heating system to be tested, and taking the load resistance value as an undetermined optimal resistance value of the photovoltaic heating system to be tested;
calculating a target load resistance value according to the following formula:
wherein R is2For the pending optimum load resistance, R1And R3Is closest to R for each resistance value of the test heating element2Resistance value of W1Is R1Corresponding output power, W2Is R2Corresponding output power, W3Is R3The corresponding output power.
The closest R mentioned here2The resistance value of (2) can be the resistance value and R of the heating element under test2The two values having the smallest absolute value of the resistance value difference. For example, R210, the resistance values of the test heating elements are respectively 8, 9, 11, 12 and 13, then R1=11、R39 or R1=9、R3=11。
And S204, calculating theoretical load resistance values of the test heating elements of the test photovoltaic heating systems according to preset rules.
In particular, it can be based on a formulaCalculating to obtain theoretical load resistance R0. For example, the maximum output power P of a photovoltaic heating systemmax550W, the working voltage V corresponding to the maximum output powermp63.6V, the theoretical load resistance R of the test heating element of the photovoltaic heating system0=Europe.
It should be noted that step S204 may be executed before step S202, may be executed after step S202, or may be executed simultaneously with step S202, which is not limited in the embodiment of the present specification.
And S205, determining the value of a according to the target load resistance value and the corresponding theoretical load resistance value.
From the ohm's law of the closed circuit, the electromotive force E and the internal resistance R of the photovoltaic heating system can be regarded as constants in the same environment, and the functional relationship P (R) between the output power P and the external circuit R is:
as shown in fig. 3, it can be seen from fig. 3 that, for the function P (R), P' (R) is made to be 0 by using the derivation rule and the extreme value principle, and R is obtained in the same manner, that is, the output power is maximum when the external resistance and the internal resistance are equal. It should be noted that the external resistor is a resistance value of a heating element in the photovoltaic heating system, the internal resistor is a resistance value of a photovoltaic element in the photovoltaic heating system, and the internal resistor changes with changes in illumination and temperature.
According to this characteristic of the function P (r), when selecting the respective resistance values of the test heating elements of the test photovoltaic heating system, the resistance values should be distributed as close as possible to the extreme points, that is, to the resistance values of the photovoltaic elements, and the basic basis is the "maximum power P" calibrated by the photovoltaic elementsmaxOperating voltage V corresponding to 'and' maximum powermp"utilization formulaAnd (4) determining the resistance interval by adopting an equivalence method.
Since it is impossible to make the above resistance interval very small, the "optimum resistance" obtained by the data obtained by the test does not correspond to the "optimum resistance" of the heat generating element. Therefore, the optimal resistance of the heating element can be obtained by the following method:
first, the relationship between the "optimal resistance" obtained by the test and the left and right resistances having similar resistances is shown in fig. 4. The problem then becomes that at known R1、R2、R3And correspondingW1、W2、W3How to obtain the R value so that the W value becomes maximum under the condition (1).
As can be seen from FIG. 4, first, when W is1=W3When it is clear that W is equal to W2I.e. R ═ R2;
When W is1>W3By the linearization process, the problem can be equivalent to the following description of the graph shown in fig. 5:
by utilizing the geometric relation of the right-angle triangle, the following equation set is established:
obtaining the following components:substituting into the third step to obtain:
when W is1<W3By the linearization process, the problem is equivalent to the description of the graph shown in fig. 6:
by using the geometric relation of the right-angle triangle, the equation system can be obtained as well:
similarly, can ask:
in summary, after the undetermined optimal load resistance value is obtained according to the actual measurement data, the calculation formula for further obtaining the target load resistance value of the photovoltaic module is as follows:
according to sample 1, P in Table 3max=315W,Vmp33.2V, two are connected in series according to the formulaTherefore, the resistance value of the heating element of each test photovoltaic heating system can be selected to be 6 ohms, 7 ohms, 8 ohms, … … ohms and 20 ohms, and the time period is selected to be 9: 00-16: 00, the preset period is half an hour, namely, data is collected once in half an hour, the measured data is shown in table 3, and table 3 is used for showing the measured data of the working voltage change of the photovoltaic element of the sample 1 in different time periods and different loads.
TABLE 3
From the above table 3, a related data table can be calculated, such as table 4, for representing the output power of the sample 1 at different time periods and different loads.
TABLE 4
Time/project
9:00
9:30
10:00
10:30
11:00
11:30
12:00
12:30
13:00
13:30
14:00
14:30
15:00
15:30
16:00
Mean value of
Intensity of illumination
34220
38965
44126
48254
50835
53932
54448
57028
55480
53932
51867
49287
45674
40513
30243
47253.6
Temperature of air
30.4
32.8
35
37.9
38.5
41
40.8
41.1
40.8
42.8
40.8
41.3
42.6
41.7
39.6
39.14
Humidity of air
51.6
45.7
37.9
33.5
33.7
29.5
32
30.1
30.7
26.8
30.9
29.9
27.4
26.8
31.6
33.2067
6 ohm
146
162.2
241.9
272
312.5
411.7
428.4
445.5
421.7
392
352.7
288.4
250.9
168.5
42.14
289.1
7 ohm
153.7
172
307.6
376
404.3
424.3
435.3
440
433.7
415
392.3
330.5
288
193.5
51.03
321.1
8 ohm
168.4
219.5
331.5
387.8
406.1
414.7
422
423.4
420.5
404.7
393.4
348.5
311.3
211.2
53.56
327.8
9 ohm
171.6
282.2
359.7
390.7
398.7
400
405.4
404
404
392
386.8
363.5
339.8
245.4
64.53
333.9
10 ohm
220
330.6
361.2
379.5
386.9
385.6
379.5
388.1
393.1
383.2
383.2
362.4
351.6
295.9
87.03
339.2
11 ohm
228.2
312.2
340.5
350.6
356.3
354
352.8
356.3
360.8
352.8
351.7
341.6
327.3
291.2
87.36
317.6
12 ohm
239.4
313.1
324.5
340.3
342.4
338.1
338.1
339.2
343.5
337.1
339.2
330.8
322.4
289.1
97.47
309
13 ohm
272.3
304.3
313.1
317
318
315.1
315.1
314.1
319
313.1
315.1
308.2
301.4
278.8
112.2
294.5
14 ohm
281.7
294.4
299
301.8
299.9
298.1
298.1
295.3
300.9
295.3
295.3
292.6
287.1
273.7
126.6
282.7
15 ohm
270.5
280.8
286
285.1
283.4
281.7
281.7
279.9
283.4
279.1
279.9
276.5
272.2
268
133.2
269.4
16 ohm
264.1
268.1
269.8
271.4
269.8
267.3
267.3
281.4
268.1
264.1
265.7
263.3
259.2
255.2
162.6
259.8
17 ohm
252.4
256.2
256.2
257
255.5
253.1
253.9
250.8
253.9
250.1
251.6
249.3
246.2
240.2
163.4
246
18 ohm
246.4
247.9
246.4
247.2
244.9
242
243.5
240.5
242.7
239.8
242
239.8
237.6
233.3
200
239.6
19 ohm
237.7
237.7
235.6
236.3
234.2
231.4
232.1
230
231.4
228.6
230.7
228.6
227.9
224.4
210.2
230.4
20 ohm
229.2
228.5
225.8
226.5
224.5
221.1
222.4
219.1
221.8
219.1
221.1
219.8
218.5
215.8
205.4
221.2
Maximum value
281.7
330.63
361.2
390.72
406.13
424.32
435.29
445.48
433.72
415.03
393.4
363.54
351.65
295.94
210.22
339.19
It should be noted that the corresponding output power calculated according to table 3 is already described above and will not be described herein again.
According to table 4, the pending optimal load resistance value for the photovoltaic element is 10 ohms. Using the above formula1=9,R2=10,R3=11,W1=333.9,W2=339.2,W3=317.6,W1>W3And calculating a target load resistance value corresponding to the photovoltaic element:
according to sample 2, P in Table 5 abovemax=435W,Vmp40.8V, monoblock, according to the formulaTherefore, the resistance value of the heating element of each photovoltaic heating system can be selected to be 2 ohm, 3 ohm, 4 ohm,. cndot.. 15 ohm, 20 ohm, the time period is selected to be 9:00-15:30, the preset period is half an hour, namely.
TABLE 5
Time/project
9:00
9:30
10:00
10:30
11:00
11:30
12:00
12:30
13:00
13:30
14:00
14:30
15:00
15:30
Intensity of illumination
18450
20385
32256
42061
49545
50093
53157
54448
47793
30578
23905
15224
12450
12192
Temperature of air
31.6
31.9
32.9
36
34.3
38.8
39.3
40.2
37.8
37.5
37.4
34.9
33.5
33
Humidity of air
56.2
53.3
55.9
46.3
51.3
38
36.3
33.3
38.6
40.5
39.8
45.4
47.2
47.7
2 ohm
5.6
6.7
5.3
12.8
15.3
15
17.5
17.4
15.5
8.3
7.3
4.5
3.8
3.7
3 ohm
8.1
9.8
15.3
19.4
19.8
23.2
26.2
26.1
22.3
14.4
11.5
6.6
5.6
5.5
4 ohm
11.1
13.2
21.2
28.8
26.3
33
34.4
34.2
29.5
22.2
16.1
9.1
7.7
7.6
5 ohm
13.9
17.7
25.3
32.3
38.4
37.3
37.8
37.7
35.8
25.2
19.4
11.6
9.8
9.8
6 ohm
18.1
21
33.8
37.2
40.9
39.6
39.9
39.7
39.4
30.5
27.2
15.2
12.9
12.8
7 ohm
21.3
20.3
37.8
40.3
41.7
40.4
40.6
40.5
40.4
34.1
32.2
17.5
15
15
8 ohm
24.1
29.7
38.9
40.8
42.2
40.9
40.8
41
40.8
38.7
34.5
19.6
16.7
16.7
9 ohm
26.8
30
40.7
41.2
42.6
41.3
41.2
41.3
41.2
40
37.1
21.6
18.5
18.4
10 ohm
29.6
31.5
41.3
41.3
42.8
41.5
41.6
41.6
41.5
40.1
38
23.8
20.2
20
11 ohm
33.2
32.1
41.7
41.5
43
41.7
41.8
41.8
41.6
40.6
38.8
24.6
21.7
21.5
12 ohm
34.8
36.2
42.1
41.7
43.2
41.9
42
42
41.8
40.8
39.5
26.7
23.4
23.2
13 ohm
37.4
38.8
42.4
42.1
43.3
42.1
42.2
42.1
42
41
40.1
28.9
25.2
25
14 ohm
39.1
40.1
42.6
42.3
43.5
42.3
42.4
42.3
42.1
41.3
40.4
31.2
27.3
27.2
15 ohm
40
40.3
42.9
43.1
43.6
42.5
42.6
42.4
42.2
41.5
40.6
33.5
29.5
29.3
20 ohm
41.2
41.8
43.6
43.5
44
43
43
42.9
42.7
42.3
41.9
39.8
37.7
37.5
According to the above table 5, a related data table, such as table 6, can be calculated to indicate the output power variation of the sample 2 at different time periods and different loads.
TABLE 6
Time/project
9:00
9:30
10:00
10:30
11:00
11:30
12:00
12:30
13:00
13:30
14:00
14:30
15:00
15:30
Mean value of
Intensity of illumination
18450
20385
32256
42061
49545
50093
53157
54448
47793
30578
23905
15224
12450
12192
34160.5
Temperature of air
31.6
31.9
32.9
36
34.3
38.8
39.3
40.2
37.8
37.5
37.4
34.9
33.5
33
35.9615
Humidity of air
56.2
53.3
55.9
46.3
51.3
38
36.3
33.3
38.6
40.5
39.8
45.4
47.2
47.7
44.1231
2 ohm
15.68
22.45
14.05
81.92
117
112.5
153.1
151.4
120.1
34.45
26.65
10.13
7.22
6.845
65.99
3 ohm
21.87
32.01
78.03
125.5
130.7
179.4
228.8
227.1
165.8
69.12
44.08
14.52
10.45
10.08
101.2
4 ohm
30.8
43.56
112.4
207.4
172.9
272.3
295.8
292.4
217.6
123.2
64.8
20.7
14.82
14.44
142.5
5 ohm
38.64
62.66
128
208.7
294.9
278.3
285.8
284.3
256.3
127
75.27
26.91
19.21
19.21
159
6 ohm
54.6
73.5
190.4
230.6
278.8
261.4
265.3
262.7
258.7
155
123.3
38.51
27.74
27.31
168.7
7 ohm
64.81
58.87
204.1
232
248.4
233.2
235.5
234.3
233.2
166.1
148.1
43.75
32.14
32.14
161.7
8 ohm
72.6
110.3
189.2
208.1
222.6
209.1
208.1
210.1
208.1
187.2
148.8
48.02
34.86
34.86
155.3
9 ohm
79.8
100
184.1
188.6
201.6
189.5
188.6
189.5
188.6
177.8
152.9
51.84
38.03
37.62
145.3
10 ohm
87.62
99.23
170.6
170.6
183.2
172.2
173.1
173.1
172.2
160.8
144.4
56.64
40.8
40
135.1
11 ohm
100.2
93.67
158.1
156.6
168.1
158.1
158.8
158.8
157.3
149.9
136.9
55.01
42.81
42.02
125.9
12 ohm
100.9
109.2
147.7
144.9
155.5
146.3
147
147
145.6
138.7
130
59.41
45.63
44.85
120.1
13 ohm
107.6
115.8
138.3
136.3
144.2
136.3
137
136.3
135.7
129.3
123.7
64.25
48.85
48.08
114.9
14 ohm
109.2
114.9
129.6
127.8
135.2
127.8
128.4
127.8
126.6
121.8
116.6
69.53
53.24
52.85
110.2
15 ohm
106.7
108.3
122.7
123.8
126.7
120.4
121
119.9
118.7
114.8
109.9
74.82
58.02
57.23
105.9
20 ohm
84.87
87.36
95.05
94.61
96.8
92.45
92.45
92.02
91.16
89.46
87.78
79.2
71.06
70.31
87.67
Maximum value
109.2
115.8
204.12
232.01
294.91
278.26
295.84
292.41
258.73
187.21
152.93
79.2
71.06
70.31
168.72
As shown in table 6, the pending optimal load resistance value corresponding to the photovoltaic element is 6 ohms. Using the above formula1=5,R2=6,R3=7,W1=159,W2=168.7,W3=161.7,W1<W3And calculating a target load resistance value corresponding to the photovoltaic element:
as known to those skilled in the art, the core parameter of different photovoltaic devices is the maximum output power PmaxWorking voltage V at maximum output powermpAnd whatever manufacturer and model of photovoltaic panel, the two parameters must be detected and labeled.
From the above, the resistance valueIs a load resistor corresponding to the maximum output power, and can also be regarded as a theoretical resistance value, i.e. a resistance valueFor the theoretical load resistance value mentioned above, this theoretical load resistance value R is then0The correlation between the target load resistance value R calculated through actual measurement is obvious, and the theoretical load resistance value R can be obtained according to the theoretical load resistance value R as long as the rule between the target load resistance value R and the theoretical load resistance value R can be found out0And calculating a target load resistance value R.
According to the two examples, R06.998, R9.6227; r03.8268, R6.193, a group of data can be obtained through actual measurement and calculation of a large number of different photovoltaic elements, and the obtained data are processed by a mathematical statistics method, so that a general calculation formula can be obtained.
For example, sample 1 and sample 2 above, and another 5 different photovoltaic modules were actually measured and calculated, and the following table 7 can be obtained.
The linear regression equation shown in fig. 7 can be obtained by performing a one-dimensional linear regression analysis on the data in table 7. As shown in FIG. 7 and R2It can be seen that 0.9938 shows that the "theoretical load resistance" calculated from the maximum output power of the photovoltaic element and the operating voltage at the time of the maximum output power has a very strong linear correlation with the optimum load resistance (i.e., the target load resistance value) obtained through actual measurement.
As shown in fig. 8, for a linear function y (x) ax, the sum of its variances:let f' (a) be 0,namely, it is
X represents theoretical load resistance value, y represents target load resistance value, and the target load resistance value can be obtained according to the actual calculation dataa=1.178。
Thereby obtaining the calculation resultResistance R of the thermal element 110TGeneral formula (iv):
because different longitudes and latitudes have different day and night changes, the air quality of different regions is different. Therefore, for the area with the illumination intensity in the first preset value range, the time period (11:00-14:00) with the illumination intensity larger than the corresponding preset value range is selected from the measured data for analog calculation, that is, the time period with good illumination is selected, and the following table 8 is obtained:
TABLE 8
Photovoltaic element
Pmax
Vmp
Theory R0
Actually measured R
R1
R2
R3
W1
W2
W3
Sample 1
630
66.4
6.998
7.333
6
7
8
394.9
420.7
412.1
Sample 2
435
40.8
3.827
5.516
5
6
7
228.8
229.3
214.1
Sample 3
550
63.6
7.354
7.114
6
7
8
367.1
379.5
369.9
Sample 4
825
95.4
11.032
9.260
8
9
10
491.6
535.3
514.3
Sample 5
1100
127.2
14.709
16.189
15
16
17
722.4
744.9
730.9
Sample 6
1375
159.0
18.386
17.393
16
17
18
929.2
947.4
943.5
Sample 7
1650
190.8
22.063
25.196
24
25
26
1100.0
1123.0
1109.0
According to the above calculation method and from table 8, a is 1.046955.
For the area with the illumination intensity in the second preset value range, the time period (11:00-13:30) with the illumination intensity larger than the corresponding preset value range is removed from the measured data (i.e. the time period with good illumination) for simulation calculation, and the following table 9 can be obtained:
TABLE 9
Photovoltaic element
Pmax
Vmp
Theory R0
Actually measured R
R1
R2
R3
W1
W2
W3
Sample 1
630
66.4
6.998
10.078
9
10
11
289.4
307.9
292.3
Sample 2
435
40.8
3.827
8.276
7
8
9
102.0
105.8
104.1
Sample 3
550
63.6
7.354
9.404
8
9
10
177.4
186.3
184.6
Sample 4
825
95.4
11.032
14.420
13
14
15
254.1
266.6
264.6
Sample 5
1100
127.2
14.709
18.754
18
19
20
385.0
388.1
382.0
Sample 6
1375
159.0
18.386
23.980
23
24
25
434.9
437.3
434.8
Sample 7
1650
190.8
22.063
27.771
27
28
29
536.0
537.3
534.9
The calculation is performed according to table 9, and a is 1.2962.
For the area with the illumination intensity in the third value range, the time period with the illumination intensity greater than the corresponding preset threshold value is removed from the measured data, i.e. the time period with good illumination (10:30-14:30) is subjected to simulation calculation, and the following table 10 is obtained:
watch 10
Photovoltaic element
Pmax
Vmp
Theory R0
Actually measured R
R1
R2
R3
W1
W2
W3
Sample 1
630
66.4
6.998
10.338
9
10
11
243.9
274.4
264.5
Sample 2
435
40.8
3.827
7.513
7
8
9
91.7
91.8
90.6
Sample 3
550
63.6
7.354
10.663
10
11
12
146.8
149.7
140.8
Sample 4
825
95.4
11.032
15.125
10
15
16
204.0
204.4
204.1
Sample 5
1100
127.2
14.709
19.946
10
19
20
301.7
309.8
307.0
Sample 6
1375
159.0
18.386
26.450
10
26
27
343.3
344.3
344.2
Sample 7
1650
190.8
22.063
30.500
10
30
31
400.8
402.0
402.0
The value of a is 1.4048.
The minimum value of the first preset value range is larger than the maximum value of the second preset value range, and the minimum value of the second preset value range is larger than the maximum value of the third preset value range.
In summary, a is selected from the range of 1.05 to 1.4 according to the sunshine condition in the area, and a may be in the range of 1.05 ≦ a ≦ 1.40, or 1.05 ≦ a ≦ 1.178, or 1.178 ≦ a ≦ 1.2962, or 1.2962 ≦ a ≦ 1.40.
That is, the area with good illumination (illumination intensity in the first preset value range) may be smaller, and the area with poor illumination (illumination intensity in the second preset value range or the third preset value range) may be larger. In addition, as can be seen from the measured data, when the illumination condition is poor, the daily average power of the photovoltaic power generation panel is obviously reduced, so that for an area with extremely poor illumination condition (the illumination intensity is in the fourth preset value range), the photovoltaic power generation significance is lost due to too low power generation efficiency, and the photovoltaic power generation panel is not suitable for installing a photovoltaic heating system.
Based on this, the photovoltaic heating system that this specification embodiment provided, on the basis of improving the output of system, provides a photovoltaic heating system of commonality to maximum adaptation is in different environment.
Based on the same idea, some embodiments of the present application further provide a method corresponding to the system.
The embodiment of the application also provides a heating element matching method of the photovoltaic heating system, wherein the photovoltaic heating system comprises: heating element, photovoltaic element, the method includes:
obtaining the maximum output power rate P of the photovoltaic elementmaxAnd the maximum output power PmaxCorresponding operating voltage Vmp;
The resistance value R of the heating element is calculated according to the following formulaT:
a is used as an influence coefficient and is more than or equal to 1.05 and less than or equal to 1.40;
wherein a is obtained by:
dividing an area in which the photovoltaic heating system is preset into a plurality of areas to be detected according to a preset electronic map;
according to a corresponding preset period, acquiring output power of a plurality of test photovoltaic heating systems arranged in each region to be tested; the resistance values of the test heating elements of the test photovoltaic heating systems in the regions to be tested are different and are set according to corresponding preset rules;
determining a target load resistance value of the test photovoltaic heating system according to the obtained output power of each test photovoltaic heating system and the resistance value of the corresponding test heating element; and
calculating theoretical load resistance values of the test photovoltaic elements of the test photovoltaic heating systems according to a preset rule;
and determining the value of a according to each target load resistance value and the corresponding theoretical load resistance value.
In some embodiments of the present application, determining a target load resistance value of each test photovoltaic heating system according to the obtained output power of each test photovoltaic heating system and a load resistance value of the corresponding test heating element specifically includes:
determining a load resistance value corresponding to the maximum output power of the test photovoltaic heating system according to the obtained output power of the test photovoltaic heating system, and taking the load resistance value as an undetermined optimal resistance value of the test photovoltaic heating system;
calculating the target load resistance value according to the following formula:
wherein R is2For the undetermined optimal resistance value, R1And R3Is closest to the resistance value of each test heating element2Resistance value of said W1Is the said R1Corresponding output power, W2Is the said R2Corresponding output power, W3Is the said R3The corresponding output power.
The embodiments in the present application are described in a progressive manner, and the same and similar parts among the embodiments can be referred to each other, and each embodiment focuses on the differences from the other embodiments. In particular, as for the method embodiment, since it is substantially similar to the system embodiment, the description is simple, and the relevant points can be referred to the partial description of the system embodiment.
The method provided by the embodiment of the application corresponds to the system one to one, so the method also has the similar beneficial technical effects as the corresponding system, and the beneficial technical effects of the system are explained in detail above, so the beneficial technical effects of the method are not described again.
It should be noted that the photovoltaic heating system and the matching method of the heating element thereof provided by the embodiment of the application are not only suitable for the photovoltaic heating field, but also suitable for the same or similar fields of photovoltaic energy storage, photovoltaic refrigeration and the like.
As will be appreciated by one skilled in the art, embodiments of the present invention may be provided as a method, system, or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.
The present invention is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the invention. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
In a typical configuration, a computing device includes one or more processors (CPUs), input/output interfaces, network interfaces, and memory.
The memory may include forms of volatile memory in a computer readable medium, Random Access Memory (RAM) and/or non-volatile memory, such as Read Only Memory (ROM) or flash memory (flash RAM). Memory is an example of a computer-readable medium.
Computer-readable media, including both non-transitory and non-transitory, removable and non-removable media, may implement information storage by any method or technology. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of computer storage media include, but are not limited to, phase change memory (PRAM), Static Random Access Memory (SRAM), Dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), Read Only Memory (ROM), Electrically Erasable Programmable Read Only Memory (EEPROM), flash memory or other memory technology, compact disc read only memory (CD-ROM), Digital Versatile Discs (DVD) or other optical storage, magnetic cassettes, magnetic tape magnetic disk storage or other magnetic storage devices, or any other non-transmission medium that can be used to store information that can be accessed by a computing device. As defined herein, computer readable media does not include transitory computer readable media (trans-entity media) such as modulated data signals and carrier waves.
It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.
The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.
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