CN112797642A - Loop heat pipe solar system controlled by accumulated liquid level difference - Google Patents

Abstract

The invention provides a loop heat pipe solar system controlled by accumulated temperature difference, wherein n liquid level sensing elements are used for sequentially calculating the liquid level L in the current time period_iAnd the liquid level Q of the previous time period_i‑1Difference D of_i＝L_i‑Q_i‑1And for n liquid level differences D_iPerforming arithmetic cumulative summation

Description

Loop heat pipe solar system controlled by accumulated liquid level difference

Technical Field

The invention belongs to the field of solar energy, and particularly relates to a solar heat collector system.

Background

With the rapid development of modern socioeconomic, the demand of human beings on energy is increasing. However, the continuous decrease and shortage of traditional energy reserves such as coal, oil, natural gas and the like causes the continuous increase of price, and the environmental pollution problem caused by the conventional fossil fuel is more serious, which greatly limits the development of society and the improvement of the life quality of human beings. Energy problems have become one of the most prominent problems in the modern world. Therefore, the search for new energy sources, especially clean energy sources without pollution, has become a hot spot of research.

Solar energy is inexhaustible clean energy and has huge resource amount, and the total amount of solar radiation energy collected on the surface of the earth every year is 1 multiplied by 10¹⁸kW.h, which is ten thousand times of the total energy consumed in the world year. The utilization of solar energy has been used as an important item for the development of new energy in all countries of the world. However, the solar radiation has a small energy density (about one kilowatt per square meter) and is discontinuous, which brings certain difficulties for large-scale exploitation and utilization. Therefore, in order to widely use solar energy, not only the technical problems should be solved, but also it is necessary to be economically competitive with conventional energy sources.

Aiming at the structure of a heat collector, the prior art has been researched and developed a lot, but the heat collecting capability is not enough on the whole, and the problem that the operation time is long and scaling is easy to happen, so that the heat collecting effect is influenced.

In any form and structure of solar collector, there is an absorption component for absorbing solar radiation, and the structure of the collector plays an important role in absorbing solar energy.

Aiming at the problems, the invention improves on the basis of the previous invention and provides a novel loop heat pipe solar heat collecting system, thereby solving the problems of low heat exchange amount of a heat pipe and uneven heat exchange.

In application, the continuous heat collection and heating of solar energy or no heating at night can cause the stability of internal fluid, namely the fluid does not flow any more or has little mobility, or the flow is stable, so that the vibration performance of the heat collection tube is greatly weakened, and the descaling and heating efficiency of the heat collection tube is influenced. There is therefore a need for improvements to the above-mentioned solar collectors. The applicant has already filed a relevant patent for this application.

However, in practice it has been found that adjusting the vibration of the tube bundle by a fixed periodic variation can result in hysteresis and excessively long or short periods. Therefore, the invention improves the previous application and intelligently controls the vibration, so that the fluid in the fluid can realize frequent vibration, and good descaling and heating effects can be realized.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a heat collecting device with a novel structure. The heat collecting device can be intelligently controlled according to parameters, and the heat utilization effect and the descaling effect are improved.

In order to achieve the purpose, the invention adopts the following technical scheme:

a loop heat pipe solar energy system controlled by accumulated liquid level difference comprises a heat collecting device, wherein the heat collecting device comprises a reflector and a heat collecting pipe box, the heat collecting device comprises a descaling stage, and the system runs in the following mode: in the descaling stage, the following modes are adopted for operation:

a liquid level detection element is arranged in the heat collection tube box and used for detecting the liquid level of fluid in the lower tube box, the liquid level detection element is in data connection with a controller, and the controller extracts liquid level data according to a time sequence;

the number of the liquid level sensing elements is n, and the liquid level L in the current time period is calculated in sequence_iAnd the liquid level Q of the previous time period_i-1Difference D of_i＝L_i-Q_i-1And for n liquid level differences D_iPerforming arithmetic cumulative summation

When the value of Y is lower than a set threshold value, the controller controls the heat collecting pipe box to stop heat collection or continue heat collection;

y is greater than 0, and when the Y is lower than the threshold value, the controller controls the heat collecting pipe box to stop collecting heat; if Y is less than 0, the threshold value is lower, and the controller controls the heat collection tube box to collect heat.

Preferably, the heat collecting device comprises a heat collecting pipe box, a left upper pipe, a right upper pipe and a heat releasing pipe group, wherein the heat collecting pipe box, the left upper pipe, the right upper pipe and the heat releasing pipe group are positioned at the lower part, the left upper pipe and the right upper pipe are positioned at the upper part of the heat collecting pipe box, the heat releasing pipe group comprises a left heat releasing pipe group and a right heat releasing pipe group, the left heat releasing pipe group is communicated with the left upper pipe and the heat collecting pipe box, the right heat releasing pipe group is communicated with the right upper pipe and the heat collecting pipe box, so that the heat collecting pipe box, the left upper pipe, the right upper pipe and the heat releasing pipe group form a closed heating fluid circulation, the heat releasing pipe groups are one or more, each heat releasing; the heat collecting pipe box comprises a first pipe orifice and a second pipe orifice, the first pipe orifice is connected with an inlet of a left heat releasing pipe group, the second pipe orifice is connected with an inlet of a right heat releasing pipe group, an outlet of the left heat releasing pipe group is connected with a left upper pipe, and an outlet of the right heat releasing pipe group is connected with a right upper pipe.

Preferably, the left and right heat-releasing tube groups are symmetrical along the middle of the heat collecting tube box.

Preferably, the heat release pipes of the left heat release pipe group are distributed around the axis of the left upper pipe, and the heat release pipes of the right heat release pipe group are distributed around the axis of the right upper pipe.

The volumes of the upper left tube 21 and the upper right tube 22 are respectively V1 and V2, the volume of the heat collection box is V3, and the included angle formed between the midpoint of the bottom of the heat collection box body and the circle centers of the upper left tube 21 and the upper right tube 22 is A, so that the following requirements are met:

(V1+V2)/V3＝a-b*sin(A/2)²-c sin (a/2); where a, b, c are parameters, sin is a triangular sine function,

0.8490< a <0.8492, 0.1302< b <0.1304, 0.0020< c < 0.0022; preferably, a is 0.8491, b is 0.1303, and c is 0.0021.

Preferably, an included angle A formed between the midpoint of the bottom of the heat collection box and the circle centers of the upper left tube 21 and the upper right tube 22 is 40-120 degrees (angle), and preferably 80-100 degrees (angle).

Preferably, 0.72< (V1+ V2)/V3< 0.85;

preferably, the radius of the heat-radiating pipe is preferably 10-40 mm; preferably 15 to 35mm, more preferably 20 to 30 mm.

The invention has the following advantages:

1. according to the invention, through the liquid level difference of the front time and the back time detected by the liquid level sensing element or the accumulated liquid level difference, the evaporation of the internal fluid can be judged to be basically saturated through the liquid level difference, and the volume of the internal fluid is basically not changed greatly. So that the fluid undergoes volume reduction to thereby realize vibration. When the liquid level difference rises to a certain degree, the internal fluid starts to enter a stable state again, and heat collection is needed to ensure that the fluid is evaporated and expanded again, so that the heat collection tube box needs to be started to collect heat.

2. The invention provides a heat collecting device with a novel structure, which can improve the heat collecting effect, improve the heat releasing capacity of a heat collecting pipe and reduce the energy consumption.

3. The heat collecting device with new structure has more heat releasing pipe groups in limited space to increase the vibration range of the pipe bundle, strengthen heat transfer and eliminate scale.

4. The heat exchange efficiency can be further improved by the arrangement of the pipe diameters and the interval distribution of the heat release pipe groups in the fluid flowing direction.

5. The invention optimizes the optimal relation of the parameters of the heat collecting device through a large amount of experiments and numerical simulation, thereby realizing the optimal heating efficiency.

Description of the drawings:

FIG. 1 is a front view of a heat collecting device according to the present invention.

FIG. 2-1 is a front view of the heat collecting system of the present invention.

Fig. 2-2 is a front view of the heat collecting system of the present invention without collecting heat.

FIGS. 2 to 3 are front views illustrating heat collection of a preferred heat collecting device according to the present invention.

FIGS. 2 to 4 are front views of the preferred heat collecting apparatus of the present invention without collecting heat.

FIG. 3 is a left side view of the heat collecting device of FIG. 1 according to the present invention.

FIG. 4 is a bottom view of the heat collecting device of FIG. 1 according to the present invention.

FIG. 5 is a schematic view showing the staggered arrangement structure of the heat releasing tube sets of the heat collecting device of the present invention.

FIG. 6 is a schematic diagram of a heat collecting device.

FIG. 7 is a cross-sectional view of a preferred hydraulic pump.

In the figure: 1. the heat radiation pipe group comprises a left heat radiation pipe group 11, a right heat radiation pipe group 12, 21, a left upper pipe, 22, a right upper pipe, 3, a free end, 4, a free end, 5, a free end, 6, a free end, 7, a heat radiation pipe, 8, a heat collection pipe box, 9, a box body, 10 a first pipe orifice, 13 a second pipe orifice, a left return pipe 14, a right return pipe 15, 16 reflectors and 17 supporting pieces;

24. right hydraulic pump, 25, left hydraulic pump, 26, right hydraulic device, 27, left hydraulic device, 28, right telescopic rod, 29, left telescopic rod, 30, eccentric wheel, 31, check valve, 32, oil cylinder, 33, stop valve, 34 and plunger.

Detailed Description

The following detailed description of embodiments of the invention refers to the accompanying drawings.

In this document, "/" denotes division and "×", "denotes multiplication, referring to formulas, if not specifically stated.

As shown in fig. 1, a heat collecting device comprises a heat collecting pipe box 8, a left upper pipe 21, a right upper pipe 22 and a heat releasing pipe group 1, wherein the heat releasing pipe group 1 comprises a left heat releasing pipe group 11 and a right heat releasing pipe group 12, the left heat releasing pipe group 11 is communicated with the left upper pipe 21 and the heat collecting pipe box 8, the right heat releasing pipe group 12 is communicated with the right upper pipe 22 and the heat collecting pipe box 8, so that the heat collecting pipe box 8, the left upper pipe 21, the right upper pipe 22 and the heat releasing pipe group 1 form a closed circulation of heating fluid, the heat collecting pipe box 8 is filled with phase change fluid, each heat releasing pipe group 1 comprises a plurality of heat releasing pipes 7 in an arc shape, the end parts of the adjacent heat releasing pipes 7 are communicated, so that the plurality of heat releasing pipes; the heat collecting tube box comprises a first tube opening 10 and a second tube opening 13, the first tube opening 10 is connected with an inlet of a left heat-releasing tube group 11, the second tube opening 13 is connected with an inlet of a right heat-releasing tube group 12, an outlet of the left heat-releasing tube group 11 is connected with a left upper tube 21, and an outlet of the right heat-releasing tube group 12 is connected with a right upper tube 22; the first nozzle 10 and the second nozzle 13 are disposed at one side of the heat collecting tube box 8. Preferably, the left and right heat-releasing tube groups 11 and 12 are symmetrical along the middle of the heat collecting tube box.

Preferably, the upper left tube 21, the upper right tube 22 and the heat-releasing tube group 1 are provided in the tank 9, and a fluid, preferably air or water, is provided in the tank 9 to flow.

Preferably, the left upper tube 21, the right upper tube 22 and the heat collecting tube box 8 extend in a horizontal direction.

Preferably, the fluid flows in a horizontal direction.

Preferably, a plurality of heat radiation tube groups 1 are arranged along the horizontal direction of the left upper tube 21, the right upper tube 22 and the heat collecting tube box 8, and the heat radiation tube groups 1 are connected in parallel.

Preferably, a left return pipe 14 is disposed between the left upper pipe 21 and the heat collecting tube box 8, and a right return pipe 15 is disposed between the right upper pipe 22 and the heat collecting tube box 8. Preferably, the return pipes are provided at both ends of the heat collecting tube box 8.

The heat collecting tube box 8 is filled with phase-change fluid, preferably vapor-liquid phase-change fluid. The fluid heats and evaporates at the heat collecting tube box 8, flows along the heat release tube bundle to the upper left pipe 21 and the upper right pipe 22, and the fluid can produce volume expansion after being heated, thereby forming steam, and the volume of steam is far greater than water, and the steam that consequently forms can carry out the flow of quick impact formula in the coil pipe. Because of volume expansion and steam flow, the free end of the heat-radiating pipe can be induced to vibrate, the vibration is transmitted to the heat-exchanging fluid in the box body 9 by the free end of the heat-exchanging pipe in the vibrating process, and the fluid can also generate disturbance with each other, so that the surrounding heat-exchanging fluid forms disturbance flow, a boundary layer is damaged, and the purpose of enhancing heat transfer is realized. The fluid is condensed and released heat on the left upper pipe and the right upper pipe and then flows back to the heat collecting pipe box through the return pipe.

According to the invention, the prior art is improved, and the upper pipe and the heat release pipe groups are respectively arranged into two groups distributed on the left side and the right side, so that the heat release pipe groups distributed on the left side and the right side can perform vibration heat exchange descaling, the heat exchange vibration area is enlarged, the vibration is more uniform, the heat exchange effect is more uniform, the heat exchange area is increased, and the heat exchange and descaling effects are enhanced.

The above-mentioned structure has carried out patent application, and this application is to above-mentioned structure further improves, reinforcing scale removal and heat transfer effect.

In the operation of the solar heat collector, although the structure has the elastic vibration descaling effect, the descaling effect needs to be further improved after long-term operation.

It has been found in research and practice that a sustained and stable heat collection results in a stable fluid formation of the internal heat collecting means, i.e. no fluid flow or little fluid flow, or a stable flow, resulting in a greatly reduced vibration performance of the heat emitting tube bank 1, thereby affecting the efficiency of descaling and heating of the tube bank 1. For example, continuous heat collection in the day, or continuous no heat collection in the night, results in reduced descaling effect, and continuous heat collection in the day or electric heating descaling in the night is adopted in the prior application, which greatly improves the heat collection effect in the day. However, the above structure requires a separate electric heating device and complicated design of the assembly associated with the electric heating, resulting in a complicated structure, and thus the heat collecting device needs to be improved as follows.

In the prior application of the inventor, a periodic heating mode is provided, and the vibration of the coil is continuously promoted by the periodic heating mode, so that the heating efficiency and the descaling effect are improved. However, adjusting the vibration of the tube bundle with a fixed periodic variation can lead to hysteresis and too long or too short a period. Therefore, the invention improves the previous application and intelligently controls the vibration, so that the fluid in the device can realize frequent vibration, and a good descaling effect is realized.

Aiming at the defects in the technology researched in the prior art, the invention provides a novel descaling heat collector capable of intelligently controlling vibration. This heat collector can realize fine scale removal effect.

The solar heat collector comprises a descaling stage, and the heat collector operates in the following mode in the descaling stage:

self-regulation vibration based on pressure

Preferably, the heat collecting device is internally provided with a pressure detecting element for detecting the pressure inside the heat collecting device, the controller extracts pressure data according to a time sequence, the pressure data of adjacent time periods are compared to obtain the pressure difference or the accumulation of the pressure difference change, and when the pressure data of adjacent time periods is lower than a threshold value, the controller controls whether the heat collecting tube box collects heat according to the detected pressure difference or the accumulation of the pressure difference change.

Through the pressure difference of the front time period and the rear time period or the accumulated pressure difference detected by the pressure sensing element, the evaporation of the fluid inside can be judged to be basically saturated through the pressure difference, the volume of the fluid inside is basically not changed greatly, the fluid inside is relatively stable under the condition, the vibration of the tube bundle at the moment is poor, and therefore adjustment is needed, the tube bundle vibrates, and heat collection is stopped. So that the fluid undergoes volume reduction to thereby realize vibration. When the pressure difference is reduced to a certain degree, the internal fluid starts to enter a stable state again, and heat collection is needed to ensure that the fluid is evaporated and expanded again, so that heat collection needs to be started.

The stable state of the fluid is judged according to the pressure difference or the accumulation of the pressure difference change, so that the result is more accurate, and the problem of error increase caused by aging due to the running time problem is solved.

Preferably, if the pressure of the previous period is P1 and the pressure of the adjacent following period is P2, if P1< P2, the controller controls to stop heat collection to the heat collecting tube box; if P1> P2, the controller controls the heat collection of the heat collection tube box when the threshold value is lower.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through sequential pressure judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if the pressure of the previous period is P1, the pressure of the adjacent following period is P2, and if P1 is P2, heat collection is judged according to the following:

if the P1 is larger than the pressure of the first data, the controller controls the heat collecting tube box to stop collecting heat; wherein the first data is greater than the pressure of the phase change fluid after the phase change; preferably the first data is a pressure at which the phase change fluid is substantially phase-changed;

and if the pressure P1 is less than or equal to the pressure of the second data, the controller controls the heat collecting tube box to continue collecting heat, wherein the pressure of the second data is less than or equal to the pressure at which the phase-change fluid does not change phase.

The first data is pressure data of a sufficient heat collection state, and the second data is pressure data of no heat collection or the beginning of heat collection. Through the judgment of the pressure, whether the current heat collecting pipe box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting pipe box is determined according to different conditions.

Preferably, the pressure sensing element is disposed within the heat collecting channel 8.

Preferably, the pressure sensing element is disposed at the free end. Through setting up at the free end, can perceive the pressure variation of free end to realize better control and regulation.

Preferably, the number of the pressure sensing elements is n, and the pressure P in the current time period is calculated in sequence_iPressure Q of the preceding period_i-1Difference D of_i＝P_i-Q_i-1And for n pressure differences D_iPerforming arithmetic cumulative summation

And when the value of Y is lower than a set threshold value, the controller controls the heat collecting pipe box to stop heat collection or continue heat collection.

Preferably, when Y is greater than 0, the controller controls the heat collecting pipe box to stop collecting heat if Y is lower than a threshold value; if Y is less than 0, the threshold value is lower, and the controller controls the heat collection tube box to collect heat.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through sequential pressure judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if Y is 0, heat collection is judged according to the following:

if P is_iIs greater than the pressure of the first data, the controller controls the heat collectionThe tube box stops collecting heat; wherein the first data is greater than the pressure of the phase change fluid after the phase change; preferably the pressure at which the phase change fluid substantially changes phase;

if P is_iThe arithmetic mean of the first data and the second data is less than the pressure of the second data, and the controller controls the heat collecting tube box to continuously collect heat, wherein the second data is less than or equal to the pressure of the phase-change fluid without phase change.

The first data is pressure data of a sufficient heat collection state, and the second data is pressure data of no heat collection or the beginning of heat collection. Through the judgment of the pressure, whether the current heat collecting pipe box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting pipe box is determined according to different conditions.

Preferably, the period of time for measuring the pressure is 1 to 10 minutes, preferably 3 to 6 minutes, and further preferably 4 minutes.

Preferably, the threshold is 100-1000 pa, preferably 500 pa.

Preferably, the pressure value may be an average pressure value over a period of the time period. The pressure at a certain moment in time may also be used. For example, preferably both are pressures at the end of the time period.

Independently adjusting vibration based on temperature

Preferably, a temperature detection element is arranged in the heat collection device and used for detecting the temperature in the heat collection device, the temperature detection element is in data connection with the controller, the controller extracts temperature data according to a time sequence, the temperature difference or the accumulation of temperature difference changes is obtained through comparison of liquid level data of adjacent time periods, and when the temperature difference or the accumulation of temperature difference changes is lower than a threshold value, the controller controls the heat collection tube box to stop heat collection or continue heat collection.

Through the temperature difference between the time before and after or the accumulated temperature difference detected by the temperature sensing element, the evaporation of the internal fluid can be judged to be basically saturated through the temperature difference, and the volume of the internal fluid is basically not changed greatly. So that the fluid undergoes volume reduction to thereby realize vibration. When the temperature difference is reduced to a certain degree, the internal fluid starts to enter a stable state again, and heat collection is needed to ensure that the fluid is evaporated and expanded again, so that the heat collection tube box needs to be started to collect heat.

The stable state of the fluid is judged according to the temperature difference or the accumulation of the temperature difference change, so that the result is more accurate, and the problem of error increase caused by aging due to the problem of operation time is solved.

Preferably, if the temperature of the previous period is T1 and the temperature of the adjacent following period is T2, if T1< T2, the controller controls the heat collecting tube box to stop collecting heat below a threshold value; if T1> T2, the controller controls the heat collecting tube box to collect heat when the threshold value is lower than the threshold value.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through the sequential temperature judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if the temperature of the previous period is T1, the temperature of the adjacent following period is T2, and if T1 is T2, heat collection is judged according to the following:

if the T1 is higher than the temperature of the first data, the controller controls the heat collecting tube box to stop collecting heat; wherein the first data is greater than the temperature of the phase change fluid after the phase change; preferably the first data is a temperature at which the phase change fluid substantially changes phase;

if the temperature T1 is less than or equal to the temperature of the second data, the controller controls the heat collecting tube box to continue collecting heat, wherein the second data is less than or equal to the temperature at which the phase change fluid does not change phase.

The first data is temperature data of a sufficient heat collection state, and the second data is temperature data of no heat collection or the beginning of heat collection. Through the judgment of the temperature, whether the current heat collecting pipe box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting pipe box is determined according to different conditions.

Preferably, the number of the temperature sensing elements is n, and the temperature T in the current time period is calculated in sequence_iTemperature Q of the preceding time period_i-1Difference D of_i＝T_i-Q_i-1And for n temperature differences D_iPerforming arithmetic cumulative summation

And when the value of Y is lower than a set threshold value, the controller controls the heat collecting pipe box to stop heat collection or continue heat collection.

Preferably, when Y is greater than 0, the controller controls the heat collecting pipe box to stop collecting heat if Y is lower than a threshold value; if Y is less than 0, the threshold value is lower, and the controller controls the heat collection tube box to collect heat.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through the sequential temperature judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if Y is 0, heat collection is judged according to the following:

if T is_iThe arithmetic mean of the first data is greater than the temperature of the first data, the controller controls the heat collecting tube box to stop collecting heat; wherein the first data is greater than the temperature of the phase change fluid after the phase change; preferably the temperature at which the phase change fluid substantially changes phase;

if T is_iThe arithmetic mean of the first data and the second data is less than the temperature of the second data, and the controller controls the heat collecting tube box to continuously collect heat, wherein the second data is less than or equal to the temperature at which the phase change fluid does not change phase.

The first data is temperature data of a sufficient heat collection state, and the second data is temperature data of no heat collection or the beginning of heat collection. Through the judgment of the temperature, whether the current heat collecting pipe box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting pipe box is determined according to different conditions.

Preferably, the period of time for measuring the temperature is 1 to 10 minutes, preferably 3 to 6 minutes, and further preferably 4 minutes.

Preferably, the threshold is 1-10 degrees Celsius, preferably 4 degrees Celsius.

Preferably, the temperature sensing element is disposed within the heat collecting channel 8.

Preferably, the temperature sensing element is disposed at the free end. Through setting up at the free end, can perceive the temperature variation of free end to realize better control and regulation.

Thirdly, automatically adjusting vibration based on liquid level

Preferably, a liquid level detection element is arranged in the heat collection tube box and used for detecting the liquid level of fluid in the lower tube box, the liquid level detection element is in data connection with the controller, the controller obtains the liquid level difference or the accumulation of the liquid level difference change through comparison of liquid level data of adjacent time periods according to the time sequence liquid level data, and when the liquid level difference or the liquid level difference change is lower than a threshold value, the controller controls the heat collection tube box to stop heat collection or continue heat collection.

Through the liquid level difference of the front time and the back time or the accumulated liquid level difference detected by the liquid level sensing element, the evaporation of the internal fluid can be judged to be basically saturated through the liquid level difference, and the volume of the internal fluid is basically not changed greatly. So that the fluid undergoes volume reduction to thereby realize vibration. When the liquid level difference rises to a certain degree, the internal fluid starts to enter a stable state again, and heat collection is needed to ensure that the fluid is evaporated and expanded again, so that the heat collection tube box needs to be started to collect heat.

The stable state of the fluid is judged according to the liquid level difference or the accumulation of the change of the liquid level difference, so that the result is more accurate, and the problem of error increase caused by aging due to the problem of operation time is solved.

Preferably, if the liquid level of the previous period is L1 and the liquid level of the adjacent following period is L2, if L1> L2, the controller controls the heat collecting tube box to stop collecting heat below a threshold value; if the L1< L2, the threshold value is lower, the controller controls the heat collecting tube box to collect heat.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through the sequential liquid level judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if the liquid level of the previous period is L1, and the liquid level of the adjacent subsequent period is L2, if L1 is L2, heat collection is judged according to the following:

if the L1 is less than the liquid level of the first data or the L1 is 0, the controller controls the heat collecting tube box to stop collecting heat; wherein the first data is greater than the liquid level of the phase-change fluid after the phase change; preferably the first data is a level at which the phase change fluid is substantially phase changed;

and if the L1 is greater than or equal to the liquid level of the second data, the controller controls the heat collecting tube box to continuously collect heat, wherein the second data is less than or equal to the liquid level at which the phase change fluid does not have phase change.

The first data is liquid level data in a full heat collection state, including liquid level of dry-out, and the second data is liquid level data without heat collection or just beginning heat collection. Through the judgment of the liquid level, whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting tube box is determined according to different conditions.

Preferably, the number of the liquid level sensing elements is n, and the liquid level L in the current time period is calculated in sequence_iAnd the liquid level Q of the previous time period_i-1Difference D of_i＝L_i-Q_i-1And for n liquid level differences D_iPerforming arithmetic cumulative summation

And when the value of Y is lower than a set threshold value, the controller controls the heat collecting pipe box to stop heat collection or continue heat collection.

Preferably, when Y is greater than 0, the controller controls the heat collecting pipe box to stop collecting heat if Y is lower than a threshold value; if Y is less than 0, the threshold value is lower, and the controller controls the heat collection tube box to collect heat.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through the sequential liquid level judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if Y is 0, heat collection is judged according to the following:

if L is_iIs less than the first dataIf the liquid level is 0, the controller controls the heat collecting tube box to stop collecting heat; wherein the first data is greater than the liquid level of the phase-change fluid after the phase change; preferably a level at which the phase change fluid is substantially phase-changed;

if L is_iThe arithmetic mean of the first data and the second data is larger than the liquid level of the second data, and the controller controls the heat collecting tube box to continuously collect heat, wherein the second data is smaller than or equal to the liquid level at which the phase change fluid does not change the phase.

The first data is liquid level data in a full heat collection state, including liquid level of dry-out, and the second data is liquid level data without heat collection or just beginning heat collection. Through the judgment of the liquid level, whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting tube box is determined according to different conditions.

Preferably, the period of time for which the measurement is also made is 1 to 10 minutes, preferably 3 to 6 minutes, and further preferably 4 minutes.

Preferably, the threshold is 1-10 mm, preferably 4 mm.

Preferably, the water level value may be an average water level value over a period of the time period. The water position at a certain moment in time may also be used. Such as preferably both water levels at the end of the time period.

Fourthly, automatically adjusting vibration based on speed

Preferably, a speed detection element is arranged in the free end of the tube bundle and used for detecting the flow speed of fluid in the free end of the tube bundle, the speed detection element is in data connection with the controller, the controller extracts speed data according to a time sequence, the speed difference or the accumulation of the speed difference change is obtained through the comparison of the speed data of adjacent time periods, and when the speed difference or the accumulation of the speed difference is lower than a threshold value, the controller controls the heat collection tube box to stop heat collection or continue heat collection.

Through the time speed difference before and after the speed sensing element detects or the accumulated speed difference, the evaporation of the internal fluid can be judged to be basically saturated through the speed difference, and the volume of the internal fluid is basically not changed greatly. So that the fluid undergoes volume reduction to thereby realize vibration. When the speed difference is reduced to a certain degree, the internal fluid starts to enter a stable state again, and heat collection is needed to ensure that the fluid is evaporated and expanded again, so that the heat collection tube box needs to be started to collect heat.

The stable state of the fluid is judged according to the speed difference or the accumulation of the speed difference change, so that the result is more accurate, and the problem of error increase caused by aging due to the running time problem is solved.

Preferably, if the speed of the previous period is V1 and the speed of the adjacent following period is V2, the controller controls the heat collecting tube box to stop collecting heat below the threshold value if V1< V2; if V1> V2, the threshold value is lower, the controller controls the heat collecting tube box to collect heat.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through the sequential speed judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if the speed of the previous period is V1, the speed of the adjacent following period is V2, and if V1 is V2, heat collection is judged according to the following:

if the V1 is greater than the speed of the first data, the controller controls the heat collecting tube box to stop collecting heat; wherein the first data is greater than the speed of the phase change fluid after the phase change; preferably the first data is the speed at which the phase change fluid is substantially phase changed;

if the V1 is less than or equal to the speed of the second data, the controller controls the heat collecting tube box to continue collecting heat, wherein the second data is less than or equal to the speed at which the phase-change fluid does not change phase.

The first data is speed data of a sufficient heat collection state, and the second data is speed data of no heat collection or the beginning of heat collection. Through the judgment of the speed, whether the current heat collecting pipe box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting pipe box is determined according to different conditions.

Preferably, the number of the speed sensing elements is n, and the speed sensing elements are sequentially countedCalculating the speed V of the current time period_iAnd the previous time speed Q_i-1Difference D of_i＝V_i-Q_i-1And for n speed differences D_iPerforming arithmetic cumulative summation

And when the value of Y is lower than a set threshold value, the controller controls the heat collecting pipe box to stop heat collection or continue heat collection.

Preferably, when Y is greater than 0, the controller controls the heat collecting pipe box to stop collecting heat if Y is lower than a threshold value; if Y is less than 0, the threshold value is lower, and the controller controls the heat collection tube box to collect heat.

And determining whether the current heat collecting tube box is in a heat collecting state or a non-heat collecting state through the sequential speed judgment, thereby determining the operation state of the heat collecting tube box according to different conditions.

Preferably, if Y is 0, heat collection is judged according to the following:

if V_iThe controller controls the heat collecting channel to stop collecting heat at a speed at which the arithmetic mean of the first data is greater than the first data; wherein the first data is greater than the speed of the phase change fluid after the phase change; preferably the rate at which the phase change fluid changes phase substantially;

if V_iThe arithmetic mean of the first data and the second data is less than the speed of the second data, and the controller controls the heat collecting tube box to continue collecting heat, wherein the second data is less than or equal to the speed of the phase-change fluid without phase change.

The first data is speed data of a sufficient heat collection state, and the second data is speed data of no heat collection or the beginning of heat collection. Through the judgment of the speed, whether the current heat collecting pipe box is in a heat collecting state or a non-heat collecting state is also determined, so that the operation state of the heat collecting pipe box is determined according to different conditions.

Preferably, the period of time for measuring the speed is 1 to 10 minutes, preferably 3 to 6 minutes, and further preferably 4 minutes.

Preferably, the threshold is 1-3 m/s, preferably 2 m/s.

Preferably, the speed value may be an average pressure value over a period of the time period. The speed at a certain moment in time may also be used. For example, preferably both are speeds at the end of the time period.

Preferably, the heat exchanger comprises a descaling process, and the heat exchange is carried out in the descaling process in the manner described above.

Preferably, the heat collecting tube box is heated or not heated by rotating the reflector. When heat collection is required (period front time), the reflecting surface of the reflector faces the sun, and when heat collection is not required (period rear time), the reflecting surface of the reflector does not face the sun. This can be achieved by means of a rotating mirror of a conventional solar tracking system, which need not be described in detail here.

Preferably, another embodiment may be adopted, in which the operation of whether to collect heat or not to collect heat is performed on the heat collecting tube box in a manner of whether the heat collecting tube box is located at the focal point of the reflector. When heat collection is required (period front time), the heat collection tube box is positioned at the focus of the reflector, and when heat collection is not required (period rear time), the heat collection tube box is not positioned at the focus of the reflector.

As shown in fig. 1, the reflector 16 is divided into two parts along the middle, a first part 161 and a second part 162, and a first part 161 and a second part 162, as shown in fig. 2. The support member 17 is a support column disposed at a lower portion of the heat collecting tube box 8, and the hydraulic telescopic rods 171 and 172 extend from the support column and are connected to the first and second portions 161 and 162, respectively. For driving the first and second parts apart or together. When the first part and the second part are combined together, the reflector 16 forms a complete reflector, and the heat collecting tube box is located at the focal position of the reflector 16 for collecting heat from the heat collecting tube box. When the first part and the second part are separated, the heat collecting pipe box is not positioned at the focus of the first part and the second part, and heat is not collected to the heat collecting pipe box.

Preferably, the hydraulic telescopic rod is connected with an actuator, the actuator drives the hydraulic telescopic rod to extend and retract, and the telescopic rod extends and retracts to change the position of the focal point of the reflecting mirror.

The hydraulic telescopic rod is connected to the support 17 in a pivoting manner.

As a modified example, as shown in fig. 2-3 and 2-4. The heat collecting device comprises a right hydraulic pump 24, a left hydraulic pump 25, a right hydraulic device 26 and a left hydraulic device 27, telescopic rods 35 and 36 are arranged at the upper parts of the right hydraulic device 26 and the left hydraulic device 27 and are connected to the lower parts of a second part 162 and a first part 161 in a pivoting mode, and the right hydraulic pump 24 and the left hydraulic pump 25 respectively drive the right hydraulic device 26 and the left hydraulic device 27 to ascend and descend.

Preferably, the device further comprises a right support bar 28 and a left support bar 29, the right support bar 28 and the left support bar 29 comprising a first part and a second part, the first part being located at the lower part, the lower end of the first part being pivotally connected to the support bar 17, the second part being a telescopic bar, the upper end of the telescopic bar being pivotally connected to the first part 162 and the second part 162. The telescoping rod may telescope within the first member. The right and left support bars 28 and 29 serve to support the mirror so that the mirror is maintained at a lower corresponding position. For example, when the first and second portions of the reflector are combined, the first and second portions are supported by the right and left support rods 28 and 29 to be maintained at corresponding positions, so that the heat collecting tube box 8 is located at the focal point of the reflector.

Preferably, the first member is a rod having an opening in the middle thereof, such that the telescopic rod is able to telescope within the first member.

Preferably, the right support rod 28 and the left support rod 29 are also hydraulically operated, and hydraulic pumps are separately provided, and the first component is a hydraulic device that drives the telescopic rods to extend and retract. The specific structure is similar to the right hydraulic device 26 and the left hydraulic device 27.

Fig. 7 shows a specific structure of the hydraulic pump. As shown in fig. 7, the hydraulic pump includes an eccentric 30, a check valve 31, a cylinder 32, a stop valve 33, and a plunger 34, wherein the eccentric 30 is connected with the plunger 34. The plunger 34 is disposed within a plunger cavity 38, the plunger cavity 38 being in communication with the hydraulic pump. The hydraulic pump comprises a cavity, a telescopic rod is arranged on the upper portion of the cavity, a plate-shaped structure 39 with the same inner diameter as the cavity of the hydraulic pump is arranged at the lower end of the telescopic rod, a rod-shaped structure 40 extends out of the middle of the plate-shaped structure, and the rod-shaped structure 40 extends out of the cavity of the hydraulic pump and is connected with a reflector.

The lower part of the cavity is provided with an oil cylinder 32, two one-way valves 31 are arranged between the oil cylinder and the telescopic rod, and liquid enters the upper part from the oil cylinder at the lower part to push the telescopic rod to move upwards; the two one-way valves are respectively arranged at the upper part and the lower part of the position where the plunger cavity is communicated with the hydraulic pump; a partition wall 37 is arranged on one side (far away from the position where the plunger cavity is communicated with the hydraulic pump) of the two check valves 31, a certain distance is reserved between the partition wall 37 and one side wall of the cavity opposite to the position where the plunger cavity is communicated with the hydraulic pump, and a stop valve 33 is arranged. By opening of the shut-off valve for liquid to flow from above into the lower cylinder 32.

When the reflector is lifted to stop the device from collecting heat, the right hydraulic pump 24 and the left hydraulic pump 25 can be driven, and the eccentric wheel 30 drives the plunger 34 to reciprocate. When the plunger 34 moves to the right, vacuum is generated in the cylinder body, and oil is sucked through the one-way valve, so that the oil suction process is completed. When the plunger 34 moves to the left, the oil in the cylinder is input into the hydraulic system through the check valve 31. The cam is continuously rotated to raise the mirror.

When the reflector is lowered to start heat collection, the stop valve 33 can be opened, oil on the upper part of the hydraulic system flows back to the oil cylinder, and then the reflector returns to the original position under the action of gravity.

Of course, hydraulic pumps are also a well-established prior art, and the embodiment of fig. 7 is presented for simplicity only and is not intended to be limiting. All hydraulic pumps of the prior art can be used.

The descaling time may preferably be performed after the solar collector is operated for a certain period of time. Preferably when the heat collecting effect is deteriorated.

Preferably, the heat release pipes of the left heat release pipe group are distributed around the axis of the left upper pipe, and the heat release pipes of the right heat release pipe group are distributed around the axis of the right upper pipe. The left upper pipe and the right upper pipe are arranged as circle centers, so that the distribution of the heat release pipes can be better ensured, and the vibration and the heating are uniform.

Preferably, the left heat-releasing tube group and the right heat-releasing tube group are both plural.

Preferably, the left heat-releasing tube group and the right heat-releasing tube group are mirror-symmetrical along a plane on which a vertical axis of the heat collecting tube box is located. Through such setting, can make the heat release pipe distribution of heat transfer more reasonable even, improve the heat transfer effect.

Preferably, the heat collecting tube box 8 has a flat tube structure. The heat absorption area is increased by arranging the flat tube structure. So that the heat collecting tube box 8 can be ensured to be positioned at the focal point of the reflector even if the installation position is a little remote.

Preferably, the left heat-releasing tube group 11 and the right heat-releasing tube group 12 are arranged in a staggered manner in the horizontal extending direction, as shown in fig. 5. Through the staggered distribution, can make to vibrate on different length and release heat and scale removal for the vibration is more even, strengthens heat transfer and scale removal effect.

Preferably, a reflecting mirror 16 is provided at a lower portion of the heat collecting device, the heat collecting tube box is located at a focal position of the reflecting mirror 16, and the left and right heat releasing tube groups are located in the fluid passage. Thereby forming a solar energy collection system.

Preferably, a support 17 is included, and the support 17 supports the heat collecting device.

Preferably, a fluid channel is included within which fluid flows. As shown in fig. 2, the heat collecting tube box 8 is located at a lower end of the fluid passage, as shown in fig. 2. The upper left tube 21, the upper right tube 22, the left heat-releasing tube group 11, and the right heat-releasing tube group 12 are provided in the fluid passage, and heat the fluid in the fluid passage by releasing heat.

Preferably, the flow direction of the fluid is the same as the direction in which the left and right upper tubes 21 and 22 and the heat collecting tube box 8 extend. Through such arrangement, the fluid scours the heat release pipe set when flowing, especially the free end of the heat release pipe set, so that the free end vibrates, heat transfer is enhanced, and the descaling effect is achieved.

Preferably, the heat release tube group 1 is provided in plural (for example, on the same side (left side or right side)) along the flow direction of the fluid in the fluid passage, and the tube diameter of the heat release tube group 1 (for example, on the same side (left side or right side)) along the flow direction of the fluid in the fluid passage becomes larger.

Along the flowing direction of the fluid, the temperature of the fluid is continuously increased, so that the heat exchange temperature difference is continuously reduced, and the heat exchange capacity is increased more and more. Through the pipe diameter grow of heat release nest of tubes, can guarantee that more steam passes through upper portion and gets into heat release nest of tubes, guarantee along fluid flow direction because the steam volume is big and the vibration is effectual to make whole heat transfer even. The distribution of steam in all heat release pipe groups is even, further strengthens heat transfer effect for the whole vibration effect is even, and the heat transfer effect increases, further improves heat transfer effect and scale removal effect.

Preferably, the heat release pipe diameter of the heat release pipe group (for example, the same side (left side or right side)) is increased along the flowing direction of the fluid in the fluid passage.

Through so setting up, avoid the fluid all to carry out the heat transfer at front, and the heat transfer of messenger increases to the rear portion as far as possible to form the heat transfer effect of similar countercurrent. Experiments show that better heat exchange effect and descaling effect can be achieved by adopting the structural design.

Preferably, the heat release pipe groups on the same side (left side or right side) are arranged in plurality along the flowing direction of the fluid in the fluid channel, and the interval between the adjacent heat release pipe groups on the same side (left side or right side) is gradually reduced from the top to the bottom. The specific effect is similar to the effect of the previous pipe diameter change.

Preferably, the spacing between the heat release pipe groups on the same side (left side or right side) along the flowing direction of the fluid in the fluid channel is increased in a decreasing amplitude. The specific effect is similar to the effect of the previous pipe diameter change.

In tests it was found that the volume, the distance of the upper left tube 21 and the upper right tube 22 and the volume of the collection tank can have an influence on the heat exchange efficiency and the homogeneity. If the volume undersize of thermal-arrest case, lead to the steam overheated, the heat can't in time be transmitted to exothermic pipe and upper left pipe upper right side, the volume is too big, lead to the steam condensation too fast, also can't transmit, upper left pipe 21 with the reason, upper right pipe 22's volume must be suitable for with thermal-arrest case volume collocation mutually, otherwise can lead to the steam condensation too fast or too slow, all can lead to the heat transfer condition to worsen, upper left pipe 21, distance also can lead to heat exchange efficiency too poor between the upper right pipe 22, the distance is too little, then exothermic pipe distributes too closely, also can influence heat exchange efficiency, upper left pipe 21, distance also need and thermal-arrest distance collocation between the case be suitable for between the upper right pipe 22 mutually, otherwise distance between them can influence the volume of the liquid or the steam that holds, then can exert an influence to the vibration of free end, thereby influence. The volumes of the upper left tube 21 and the upper right tube 22, the distance and the volume of the heat collecting tank have a certain relation.

The invention provides an optimal size relation summarized by numerical simulation and test data of a plurality of heat pipes with different sizes. Starting from the maximum heat exchange amount in the heat exchange effect, nearly 200 forms are calculated. The dimensional relationship is as follows:

the volumes of the upper left tube 21 and the upper right tube 22 are respectively V1 and V2, the volume of the heat collection box is V3, and the included angle formed between the midpoint of the bottom of the heat collection box body and the circle centers of the upper left tube 21 and the upper right tube 22 is A, so that the following requirements are met:

(V1+V2)/V3＝a-b*sin(A/2)²-c sin (a/2); where a, b, c are parameters, sin is a triangular sine function,

0.8490< a <0.8492, 0.1302< b <0.1304, 0.0020< c < 0.0022; preferably, a is 0.8491, b is 0.1303, and c is 0.0021.

Preferably, an included angle A formed between the midpoint of the bottom of the heat collection box and the circle centers of the upper left tube 21 and the upper right tube 22 is 40-120 degrees (angle), and preferably 80-100 degrees (angle).

Preferably, 0.72< (V1+ V2)/V3< 0.85;

the distance between the center of the upper left tube 21 and the center of the upper right tube 22 is M, the tube diameter of the upper left tube 21 and the radius of the upper right tube 22 are the same, B is B, the radius of the axis of the innermost heat radiation tube in the heat radiation tubes is N1, the radius of the axis of the outermost heat radiation tube is W2,

preferably, 35< B <61 mm; 230< M <385 mm; 69< N1<121mm, 119< W2<201 mm.

Preferably, the number of the heat release pipes of the heat release pipe group is 3 to 5, preferably 3 or 4.

Preferably, the radius of the heat-radiating pipe is preferably 10-40 mm; preferably 15 to 35mm, more preferably 20 to 30 mm.

Preferably, the arc between the ends of the free ends 3, 4, centered on the central axis of the left header, is 95-130 degrees, preferably 120 degrees. The same applies to the curvature of the free ends 5, 6 and the free ends 3, 4. Through the design of the preferable included angle, the vibration of the free end is optimal, and therefore the heating efficiency is optimal.

Preferably, V1 ═ V2.

In the prior application, only by considering that the distance between the center of the upper left tube 21 and the center of the upper right tube 22 is M, the tube diameters of the upper left tube 21 and the upper right tube 22 are the same, and B is B, the radius of the axis of the innermost heat radiation tube in the heat radiation tubes is N1, and the radius of the axis of the outermost heat radiation tube is W2, the volumes and the distances of the upper left tube 21 and the upper right tube 22 and the volume of the heat collection box are firstly related through an optimized relational expression, and an optimal dimensional relation is obtained. The above relation formula of the present application is a further improvement of the relation formula of the previous application, and belongs to the original invention point of the present invention through the relation formula of the volume and the included angle.

Preferably, the tube bundle of the heat-releasing tube group 1 is an elastic tube bundle.

The heat exchange coefficient can be further improved by arranging the tube bundle of the heat release tube group 1 with an elastic tube bundle.

The number of the heat release pipe groups 1 is plural, and the plurality of the heat release pipe groups 1 are in a parallel structure.

Although the present invention has been described with reference to the preferred embodiments, it is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (2)

1. A loop heat pipe solar energy system controlled by accumulated liquid level difference comprises a heat collecting device, wherein the heat collecting device comprises a reflector and a heat collecting pipe box, the heat collecting device comprises a descaling stage, and the system runs in the following mode: in the descaling stage, the following modes are adopted for operation:

a liquid level detection element is arranged in the heat collection tube box and used for detecting the liquid level of fluid in the lower tube box, the liquid level detection element is in data connection with a controller, and the controller extracts liquid level data according to a time sequence;

the number of the liquid level sensing elements is n, and the liquid level L in the current time period is calculated in sequence_iAnd the liquid level Q of the previous time period_i-1Difference D of_i＝L_i-Q_i-1And for n liquid level differences D_iPerforming arithmetic cumulative summation

When the value of Y is lower than a set threshold value, the controller controls the heat collecting pipe box to stop heat collection or continue heat collection;

y is greater than 0, and when the Y is lower than the threshold value, the controller controls the heat collecting pipe box to stop collecting heat; if Y is less than 0, the threshold value is lower, and the controller controls the heat collection tube box to collect heat.

2. The utility model provides a heat transfer device, heat transfer device is including the thermal-arrest pipe case, upper left pipe, upper right pipe and the heat release nest of tubes that are located the lower part, and upper left pipe, upper right pipe are located the upper portion of thermal-arrest pipe case. .

Images