JP2012127536A - Solar heat collector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar heat collector capable of automatically avoiding an abnormal state or an accident caused by the overheating of a heat collection pipe when heat transfer to a heat medium circulating in the heat collecting pipe is obstructed.SOLUTION: The solar heat collector receives solar light condensed by a light condensing mechanism 1 by the heat collection pipe 2, transfers energy to the heat medium circulating in the heat collection pipe 2 and is provided with a solar tracking mechanism 5 which moves the light condensing mechanism 1 in accordance with the movement of the sun so that the light condensing mechanism 1 is pointed to the direction of the sun at all times, where, when heat transfer to the heat medium circulating in the heat collection pipe 2 is obstructed, there is disposed a saving mechanism 5 which moves the light condensing mechanism 1 up to a position where the heat collection pipe 2 is not irradiated with at least a part of solar light condensed by the light condensing mechanism 1.

Description

  The present invention relates to a solar heat collecting apparatus, and more particularly, a solar light collecting device that receives sunlight collected by a light collecting mechanism with a heat collecting tube and transmits energy to a heat medium that circulates inside the heat collecting tube. It relates to a thermal device.

  In a solar heat collecting apparatus, various condensing mechanisms such as a parabolic trough condensing mechanism and a Fresnel condensing mechanism are used as a condensing mechanism for securing a heat source. Is received by a heat collecting tube, and energy is transmitted to a heat medium circulating in the heat collecting tube.

  By the way, in order to exhibit the light collecting mechanism and its maximum ability, the movement of the sun so that the light collecting mechanism always points in the direction of the sun so that the most concentrated sunlight can be received by the heat collecting tube. A sun tracking mechanism for moving the light collecting mechanism is provided.

A conventional solar tracking mechanism will be described by taking a solar heat collecting apparatus having a parabolic trough type condensing mechanism shown in FIG. 1 as an example.
This solar heat collecting apparatus includes a reflecting mirror 1 as a parabolic trough type condensing mechanism, a heat collecting tube 2 through which a heat medium circulates in an interior located at a focal point where sunlight reflected by the reflecting mirror 1 converges, and a heat collecting tube And a heat insulating tube 3 made of glass arranged concentrically on the outer periphery of the heat collecting tube 2, and the heat medium flowing through the heat collecting tube 2 is heated by the energy of sunlight focused on the heat collecting tube 2. To be collected as.
In this solar heat collecting apparatus, the reflecting mirror 1 and the heat collecting pipe 2 are integrated, and the driving device 5 as a sun tracking mechanism is moved through the swing shaft 4 so as to follow the movement of the sun. The maximum heat input is performed on the heat collecting tube 2.
In the example shown in FIG. 1, the reflecting mirror 1 and the heat collecting tube 2 are arranged so that the horizontal axis faces north and south.

In this case, in order to recover the maximum energy, with respect to the parallel ray angle of the sun at that time,
(1) Method for controlling the attitude angle of the opening of the reflecting mirror 1 so as to be always vertical (2) Method for controlling the attitude angle of the opening of the reflecting mirror 1 so as to maximize the amount of incident direct rays of light (3) One of the methods of controlling the attitude angle of the opening of the reflecting mirror 1 so that the amount of light focused on the heat tube 2 is maximized, is automatically tracked automatically, and the heat input tube 2 always receives the maximum heat input. It is supposed to be.

The tracking method includes
(1) A method of calculating the angle of the reflecting mirror 1 by a timer at each time (2) A physical quantity (amount of heat input to the heat collecting tube 2) of a method of controlling the actual posture angle of the above (1) to (3) is always set There is a method of measuring and PID control.

By the way, in the above-described conventional control method, for example, the solar heat collecting apparatus is operated to always obtain the maximum heat input amount even under the maximum heat input operation condition in summer.
In the operation of such a solar heat collecting apparatus, when the heat transfer to the heat medium that circulates inside the heat collecting pipe 2 is performed smoothly, the amount of heat conversion as the plant is maximized, and there is no problem. Absent.

However, once the heat transfer is hindered, for example, in the case of a heat medium such as oil, the flow rate of the heat medium is too low, and in the case of a heat medium that directly evaporates, the mass flow rate in the boiling region or the superheated region. When the temperature is too small, heat transport is delayed due to excessive heat input, causing various problems.
Specifically, the outer surface of the heat collecting tube 2 is abnormally heated, and the heat collecting tube 2 may be locally deformed and damaged. Moreover, the temperature of the heat collecting tube 2 may locally rise above the transformation point of the material, and the soundness of the heat collecting tube 2 itself may be impaired. In addition, there is a risk that functions for improving the heat collection efficiency of the heat collection tube 2, for example, functional degradation of a selective absorption film, an antireflection film, and the like may occur.

  In view of the actual situation of the conventional solar heat collecting apparatus, the present invention automatically detects an abnormal state or accident caused by overheating of the heat collecting tube when heat transfer to the heat medium flowing through the heat collecting tube is hindered. An object of the present invention is to provide a solar heat collecting apparatus which can be avoided.

  In order to achieve the above object, the solar heat collecting apparatus of the present invention receives sunlight collected by a light collecting mechanism with a heat collecting tube, and transmits energy to a heat medium that circulates inside the heat collecting tube. And a solar heat collecting apparatus provided with a solar tracking mechanism that moves the light collecting mechanism according to the movement of the sun so that the light collecting mechanism always points in the direction of the sun, to a heat medium that circulates inside the heat collecting tube When the heat transfer is hindered, a retracting mechanism is provided that moves the light collecting mechanism to a position where at least a part of the sunlight collected by the light collecting mechanism is not irradiated to the heat collecting tube.

In this case, it can be detected by any one or a combination of the following (a) to (d) that the heat transfer to the heat medium flowing through the inside of the heat collecting tube is inhibited. .
(A) When the surface temperature of the heat collecting tube exceeds the allowable value (b) When the temperature of the heat medium exceeds the allowable value (c) When the pressure of the heat medium exceeds the allowable value (d) Flow rate of the heat medium Is reduced beyond the allowable value

  According to the solar heat collecting apparatus of the present invention, when heat transfer to the heat medium that circulates inside the heat collecting tube is inhibited, at least a part of the sunlight collected by the light collecting mechanism is transferred to the heat collecting tube. By providing a retracting mechanism that moves the light collecting mechanism to a position where it is not irradiated, it is possible to automatically avoid an abnormal state or an accident caused by overheating of the heat collecting tube.

It is explanatory drawing of a solar heat collecting device. It is explanatory drawing which shows the state which receives the sunlight condensed by the reflective mirror with a heat collecting tube. It is explanatory drawing which shows the state which receives the sunlight condensed with the reflective mirror at the time of normal operation with a heat collecting tube. It is explanatory drawing which shows the state which receives the sunlight condensed with the reflective mirror in the state which actuated the retracting mechanism with a heat collecting tube. It is a flowchart which shows an example of the operating method of a solar heat collecting device.

  Hereinafter, embodiments of the solar heat collecting apparatus of the present invention will be described with reference to the drawings.

  The solar heat collecting apparatus of the present invention will be described by taking a solar heat collecting apparatus provided with a parabolic trough condensing mechanism shown in FIG. 1 as an example.

  The solar heat collecting apparatus receives sunlight collected by a reflecting mirror 1 as a light collecting mechanism by a heat collecting tube 2 and transmits energy to a heat medium circulating in the heat collecting tube 2. In a solar heat collecting apparatus provided with a drive device 5 as a solar tracking mechanism that moves the reflecting mirror 1 through the swing shaft 4 according to the movement of the sun so that the reflecting mirror 1 always points in the direction of the sun. When it is detected that heat transfer to the heat medium flowing through the inside of the heat tube 2 is inhibited, the reflecting mirror 1 is moved to a position where at least a part of the sunlight collected by the reflecting mirror 1 is not irradiated on the heat collecting tube 2. Is provided with a retracting mechanism (in this embodiment, shared with the driving device 5 as a solar tracking mechanism), and thereby an abnormal state or accident caused by overheating of the heat collecting tube 2 is provided. Automatically avoid Unishi to have.

In this case, the detection that the heat transfer to the heat medium flowing through the inside of the heat collecting tube 2 is inhibited can be performed by any one or a combination of the following (a) to (d), for example.
(A) When the surface temperature of the heat collecting tube exceeds the allowable value (b) When the temperature of the heat medium exceeds the allowable value (c) When the pressure of the heat medium exceeds the allowable value (d) Flow rate of the heat medium Is reduced beyond the allowable value

  When it is detected that the heat transfer to the heat medium that circulates inside the heat collecting tube 2 is detected during the operation of the solar heat collecting apparatus, the reflecting mirror is used from the viewpoint of protecting the solar heat collecting apparatus. The reflecting mirror 1 is oscillated and moved (retracting angle: -α) via the oscillating shaft 4 to a retracted position where at least a part, preferably all of the sunlight collected by 1 is not irradiated on the heat collecting tube 2.

In this case, the direction in which the reflecting mirror 1 is oscillated and moved through the oscillating shaft 4 is set in the direction opposite to the oscillating movement direction (tracking direction) by the normal sun tracking mechanism.
At this time, the reason for the rocking movement in the direction opposite to the tracking direction is that if the abnormal factor is not eliminated when the movement is moved to the retracted position in the forward direction, the sunlight collected again by the reflecting mirror 1 over time is recovered. This is for avoiding the situation of irradiating 2.

Then, when the abnormal factor that hinders the heat transfer to the heat medium flowing through the heat collecting pipe 2 is eliminated and the measurement physical quantity (temperature / pressure) that is the detection target reaches the safe region, it is normal again. Return to the operation of the solar collector.
An example of a flowchart of the operation of the solar heat collecting apparatus is shown in FIG.

  By the way, in the case of the parabolic trough type condensing mechanism shown in FIG.

αcritical：反射鏡１の限界待避角度［ｄｅｇ］
Ｗ：反射鏡１の開口幅［ｍ］
Ａ：反射鏡１の放物面の２次係数
Ｆ：焦点距離
Ｄ：レシーバ（断熱管３）の外径［ｍ］

αcritical: Limiting retract angle of reflector 1 [deg]
W: Opening width of the reflecting mirror 1 [m]
A: Second-order coefficient of paraboloid of reflecting mirror 1 F: Focal length D: Outer diameter [m] of receiver (insulating tube 3)

According to this solar heat collecting apparatus, during normal operation, as shown in FIG. 3, all of the sunlight collected by the reflecting mirror 1 is focused on the receiver (heat collecting tube 2) (from the receiver). The attitude control of the reflecting mirror 1 is performed so as to track the sun by the drive device 5 as the sun tracking mechanism.
On the other hand, when it is detected that the heat transfer to the heat medium flowing through the inside of the heat collecting tube 2 is inhibited during the operation of the solar heat collecting apparatus, the reflecting mirror 1 is used by the driving device 5 as a retraction mechanism. By oscillating and moving the reflecting mirror 1 via the oscillating shaft 4 (retraction angle: −α) to a retreat position where at least a part, preferably all of the collected sunlight is not irradiated onto the heat collecting tube 2, As shown in FIG. 4, the sunlight collected by the reflecting mirror 1 is detached from the receiver (the heat collecting tube 2 and the heat insulating tube 3), and an abnormal state or accident caused by overheating of the receiver (the heat collecting tube 2 and the heat insulating tube 3). Can be avoided automatically.

  In the present embodiment, the solar heat collecting apparatus provided with the parabolic trough type condensing mechanism has been described as an example. However, as the condensing mechanism, a Fresnel mirror type reflecting mirror composed of a plurality of long planar split mirrors is used. It can be similarly applied to a solar heat collecting apparatus having a known light collecting mechanism such as a linear Fresnel lens, and this is not excluded.

  As mentioned above, although the solar heat collecting apparatus of this invention was demonstrated based on the Example, this invention is not limited to the structure described in the said Example, The structure suitably in the range which does not deviate from the meaning. Can be changed.

  The solar heat collecting apparatus of the present invention can automatically avoid an abnormal state or an accident caused by overheating of the heat collecting tube when heat transfer to the heat medium flowing through the heat collecting tube is hindered. Therefore, it can be suitably used for solar heat collector applications used in areas where the change in the incident angle of sunlight is large, and also for solar heat collector apparatuses used in other areas. Can be used.

1 Reflector (Condensing mechanism)
2 Heat collection tube (receiver)
3 Insulation pipe (receiver)
4 Oscillating shaft 5 Drive unit (sun tracking mechanism, retract mechanism)

Claims (2)

  The sunlight collected by the condensing mechanism is received by the heat collecting tube, and energy is transmitted to the heat medium circulating in the heat collecting tube, and the condensing mechanism is always directed toward the sun. In a solar heat collecting apparatus provided with a solar tracking mechanism that moves the light collecting mechanism according to the movement of the heat collecting mechanism, when the heat transfer to the heat medium that circulates inside the heat collecting tube is obstructed, the light is collected by the light collecting mechanism. A solar heat collecting apparatus comprising a retracting mechanism for moving the light collecting mechanism to a position where at least a part of the sunlight is not irradiated to the heat collecting tube. The fact that any one or a combination of the following (a) to (d) is detected that the heat transfer to the heat medium flowing through the inside of the heat collecting tube is hindered. The solar heat collecting apparatus of 1.
(A) When the surface temperature of the heat collecting tube exceeds the allowable value (b) When the temperature of the heat medium exceeds the allowable value (c) When the pressure of the heat medium exceeds the allowable value (d) Flow rate of the heat medium Is reduced beyond the allowable value

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