CN204166393U - A kind of twin shaft parabolic type groove type solar thermal-arrest compare device - Google Patents

Abstract

The utility model discloses a dual-axis parabolic trough-type solar heat collection comparison device, which comprises a dual-axis tracking device, a metal support mechanism, a parabolic concentrator, a straight-through vacuum tube heat collector, a cavity type heat collector, and a working medium tube. Road and data acquisition instrument, the biaxial tracking device is connected to a metal support mechanism, and a parabolic concentrator, a straight-through vacuum tube heat collector, a cavity heat collector, a straight-through vacuum tube heat collector, a cavity heat collector are installed on the metal support mechanism The bulk collector is set at the focal line of the parabolic concentrator. The utility model has the advantages of simple structure and convenient use, can realize performance comparison experiments of different heat collectors on the same platform, and has important practical significance and application value for the research of various new cavity type heat collectors.

Description

A dual-axis parabolic trough solar heat collection comparison device

technical field

The utility model mainly relates to the field of solar energy research, in particular to a dual-axis parabolic trough-type solar heat collection contrast device.

Background technique

As a new energy source, solar energy can be said to be inexhaustible and inexhaustible. At present, more than 60 countries in the world are researching and utilizing solar energy to varying degrees. At present, solar energy utilization mainly includes solar water heaters, solar thermal power generation, Solar photovoltaic power generation and other technologies.

As a device that converts solar energy into heat energy, solar collectors play an important role in solar energy systems. Their efficiency and price directly affect the efficiency and economy of the entire solar energy system. Common trough-type concentrating heat-collecting devices mostly use straight-through Glass-metal vacuum tubes are used as heat collectors, which have problems such as high cost, long-term operation is prone to vacuum leakage, and when the temperature is high, the thermal expansion difference between glass and metal will cause glass breakage and low reliability. In addition to the vacuum tube, the cavity collector is also another absorption device used. The cavity absorber is used as the heat collecting element of the parabolic trough solar collector, and there is no disadvantage of the straight-through vacuum tube collector, and because The black cavity effect of the cavity absorber can effectively improve the optical efficiency of the absorber and reduce the heat loss of the absorber. The cost of the cavity collector is low and the reliability is high. Therefore, various new cavity collectors and vacuum tube collectors The comparative study of comprehensive performance between devices has important practical significance and application value.

Utility model content

The utility model provides a dual-axis parabolic trough-type solar heat collection comparison device, which can simultaneously support a straight-through vacuum tube heat collector and a cavity-type heat collector, and realize a performance comparison experiment of two different heat collectors on the same platform.

In order to achieve the above object, the technical scheme of the utility model is as follows:

A dual-axis parabolic trough solar heat collection comparison device, including a dual-axis tracking device, a metal support mechanism, a parabolic concentrator, a straight-through vacuum tube heat collector, a cavity heat collector, a working medium pipeline, and a data acquisition instrument , the biaxial tracking device is connected to a metal support mechanism, and a parabolic concentrator, a straight-through vacuum tube heat collector, and a cavity-type heat collector are installed on the metal support mechanism, and the straight-through vacuum tube heat collector, cavity-type heat collector The collector is set at the focal line of the parabolic concentrator, the first working fluid outlet of the straight-through vacuum tube collector is equipped with a first working fluid outlet temperature sensor, and the cavity type collector is equipped with a second working fluid outlet temperature sensor. The first working fluid outlet temperature sensor and the second working fluid outlet temperature sensor are connected to the data acquisition instrument.

Further, the metal support mechanism includes a heat collector bracket, and adjusting screw rods are arranged at both ends of the heat collector bracket, and the clamp is connected between the two adjusting screw rods through an adjusting nut.

Further, the straight-through vacuum tube heat collector and the cavity type heat collector are connected to the same working medium inlet of the working medium pipeline, and a working medium inlet temperature sensor is installed at the working medium inlet.

The beneficial effects of the utility model:

1. The structure is simple, the cost is low, and the use is convenient. The utility model can support the straight-through vacuum tube heat collector and the cavity type heat collector at the same time. The two heat collectors work independently, so that the performance of different heat collectors on the same platform can be realized. The comparison experiment has important practical significance and application value for the comprehensive performance comparison between various new cavity collectors and vacuum tube collectors. On this basis, further research on the performance of cavity collectors can be made. .

2. The bracket for fixing the heat collector of the utility model adopts the clamp form, and the clamp is fixed by adjusting nuts, which makes the installation and replacement of the heat collector easier and quicker, considering the possible errors in the processing process of the parabolic trough concentrator , There is an adjustment screw on the bracket, which can fine-tune the heat collector, so that the heat collector is in the best focusing position, and the heat collection efficiency is improved.

3. The straight-through vacuum tube heat collector and the cavity type heat collector of the utility model are connected to the same working fluid inlet, and a temperature sensor is installed at the working fluid inlet and outlet, so that the utility model can not only test and compare the characteristics of the two heat collectors, but also The heat collection performance of each collector is studied individually.

4. The utility model adopts a dual-axis tracking device, which can accurately track the movement of the sun, so that the equipment can receive sunlight energy to the maximum extent, and the experimental efficiency is improved.

Description of drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following will briefly introduce the drawings required for the description of the embodiments or the prior art.

Accompanying drawing 1 is the utility model overall structure schematic diagram.

Accompanying drawing 2 is the structural schematic diagram of the heat collector support of the present invention.

Accompanying drawing 3 is the structural schematic diagram of the working fluid pipeline of the utility model.

Numbers shown in the drawings: 1. Biaxial tracking device; 2. Metal support mechanism; 3. Collector bracket; 4. Straight-through vacuum tube collector; 5. Parabolic concentrator; 6. Cavity collector ; 7. Adjusting screw rod; 8. Adjusting nut; 9. Clamp; 10. Working fluid inlet; 11. Working fluid inlet temperature sensor; 12. First working fluid outlet; 13. First working fluid outlet temperature sensor; 14. The outlet of the second working fluid; 15. The temperature sensor at the outlet of the second working fluid.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of them. example. Based on the embodiments of the present utility model, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the scope of protection of the present utility model.

As shown in Figure 1, a biaxial parabolic trough solar heat collection comparison device is characterized in that it includes a biaxial tracking device 1, a metal support mechanism 2, a parabolic concentrator 5, a straight-through vacuum tube heat collector 4, Cavity heat collector 6, working medium pipeline and data acquisition instrument, the biaxial tracking device 1 is connected to a metal support mechanism 2, and a parabolic concentrator 5 and a straight-through vacuum tube heat collector 4 are installed on the metal support mechanism 2 , cavity type heat collector 6, the straight-through vacuum tube heat collector 4 and the cavity type heat collector 6 are arranged at the focal line of the parabolic concentrator 5, and the first working medium outlet 12 of the straight-through vacuum tube heat collector 4 is set at the second A working fluid outlet temperature sensor 13, the second working fluid outlet 14 of the cavity collector 6 is provided with a second working fluid outlet temperature sensor 15, the first working fluid outlet temperature sensor 13 and the second working fluid outlet temperature sensor 15 are connected to data acquisition instrument. The two heat collectors are components that work independently, and they are set on the same platform. The external environment and solar radiation conditions are the same, and the performance comparison between the straight-through vacuum heat collector and the cavity heat collector under the same platform is realized. experiment.

The utility model is further characterized in that: the metal support mechanism 2 includes a heat collector support 3, and the two ends of the heat collector support 3 are provided with adjustment screw rods 7, and the clip 9 is connected between the two adjustment screw rods 7 through an adjustment nut 8. between. Considering the manufacturing error, it may lead to the cheapness of the focal line, so the adjustment screw can fine-tune the position of the heat collector, so that the heat collector is in the best focusing position, and improve the heat collection efficiency. It is convenient and quick to install the collector.

The utility model is further characterized in that: the straight-through vacuum tube heat collector 4 and the cavity type heat collector 6 are connected to the same working medium inlet 10 of the working medium pipeline, and a working medium inlet temperature sensor 11 is installed at the 10 working medium inlets .

The utility model is simple in structure and easy to use, and can simultaneously support a straight-through vacuum tube heat collector and a cavity type heat collector, so that performance comparison experiments of different heat collectors can be carried out on the same platform, and the support structure for fixing the heat collector is increased The heat collection efficiency is improved, and the installation and replacement of the heat collector is convenient. A temperature sensor is installed at the inlet of the working fluid to test the heat collection performance of each heat collector.

Example:

Example 1: A dual-axis parabolic trough solar heat collection comparison device, including a dual-axis tracking device 1, a metal support mechanism 2, a parabolic concentrator 5, a straight-through vacuum tube collector 4, and a cavity collector 6 , working medium pipeline and data acquisition instrument, the biaxial tracking device 1 is connected to a metal support mechanism 2, and a parabolic concentrator 5, a straight-through vacuum tube heat collector 4, and a cavity type heat collector are installed on the metal support mechanism 2 6. The straight-through vacuum tube heat collector 4 and cavity type heat collector 6 are arranged at the focal line of the parabolic concentrator 5, and the first working medium outlet 12 of the straight-through vacuum tube heat collector 4 is provided with a first working medium outlet temperature sensor 13, The second working fluid outlet 14 of the cavity collector 6 is provided with a second working fluid outlet temperature sensor 15, and the first working fluid outlet temperature sensor 13 and the second working fluid outlet temperature sensor 15 are connected to a data acquisition instrument. The metal support mechanism 2 includes a heat collector bracket 3, and the heat collector bracket 3 is provided with an adjusting screw rod 7, an adjusting nut 8, and a clamp 9, and the clamp 9 is connected to two adjusting screw rods 7 through an adjusting nut 8. between. The beneficial effect of this embodiment is that: the utility model can carry out the performance comparison experiment of the straight-through vacuum tube heat collector and the cavity type heat collector under the same platform, the installation and replacement of the heat collector are convenient and quick, and the heat collector bracket can The installation position of the heater is fine-tuned to increase the heat collection efficiency.

Example 2: A dual-axis parabolic trough-type solar heat collection comparison device, including a dual-axis tracking device 1, a metal support mechanism 2, a parabolic concentrator 5, a straight-through vacuum tube collector 4, and a cavity-type collector 6 , working medium pipeline and data acquisition instrument, the biaxial tracking device 1 is connected to a metal support mechanism 2, and a parabolic concentrator 5, a straight-through vacuum tube heat collector 4, and a cavity type heat collector are installed on the metal support mechanism 2 6. The straight-through vacuum tube heat collector 4 and cavity type heat collector 6 are arranged at the focal line of the parabolic concentrator 5, and the first working medium outlet 12 of the straight-through vacuum tube heat collector 4 is provided with a first working medium outlet temperature sensor 13, The second working fluid outlet 14 of the cavity collector 6 is provided with a second working fluid outlet temperature sensor 15, and the first working fluid outlet temperature sensor 13 and the second working fluid outlet temperature sensor 15 are connected to a data acquisition instrument. The straight-through vacuum tube heat collector 4 and cavity type heat collector 6 are connected to the same working medium inlet 10 of the working medium pipeline, and a working medium inlet temperature sensor 11 is installed at the working medium inlet 10 . The beneficial effect of this embodiment is that: the utility model can carry out the performance comparison experiment of the straight-through vacuum tube heat collector and the cavity type heat collector under the same platform, and can also independently study the heat collection performance of each heat collector.

Claims (3)

1. a twin shaft parabolic type groove type solar thermal-arrest compare device, it is characterized in that: comprise double-axis tracking device (1), metallic support mechanism (2), parabolic condenser (5), straight-through vacuum tube heat collector (4), cavity type heat collector (6), working medium pipeline and data collecting instrument, described double-axis tracking device (1) connection metal supporting mechanism (2), described metallic support mechanism (2) installs parabolic condenser (5), straight-through vacuum tube heat collector (4), cavity type heat collector (6), described straight-through vacuum tube heat collector (4), cavity type heat collector (6) is arranged on parabolic condenser (5) focal line place, straight-through vacuum tube heat collector (4) first sender property outlet (12) arranges the first sender property outlet temperature sensor (13), cavity type heat collector (6) second sender property outlet (14) arranges the second sender property outlet temperature sensor (15), first sender property outlet temperature sensor (13) and the second sender property outlet temperature sensor (15) connection data Acquisition Instrument.

2. twin shaft parabolic type groove type solar thermal-arrest compare device as claimed in claim 1, it is characterized in that: described metallic support mechanism (2) comprises collector bracket (3), collector bracket (3) two ends are provided with and regulate screw mandrel (7), and clip (9) is connected between two adjustment screw mandrels (7) by adjusting nut (8).

3. twin shaft parabolic type groove type solar thermal-arrest compare device as claimed in claim 1, it is characterized in that: described straight-through vacuum tube heat collector (4), cavity type heat collector (6) connect the same working medium import (10) of working medium pipeline, and working medium inlet temperature sensor (11) is installed at described working medium import (10) place.