1. Field of the Invention
The present invention relates to a control method and a control device, more particularly to a stirring control method and a stirring control device for a combustion apparatus which burns fuel material to generate heat energy.
2. Description of the Related Art
In general, a raw material may be burned to generate usable heat energy even if the raw material such as hull and shell waste of agricultural crops is inedible. Heat exchange furnaces disclosed in U.S. Pat. Nos. 7,422,429 and 7, 393, 206 may generate usable heat energy by means of burning the raw material, so as to achieve effects of resource recycling and energy reuse.
A great amount of dust and ash, and high temperature fumes not less than about one thousand degrees centigrade are generated as a result of burning the raw material. Therefore, in order to prevent ash from blocking the aforesaid furnace and adversely affecting combustion efficiency of the raw material, currently, a stirring device is adopted for stirring a lower part of the raw material and the ash generated from burning the raw material so as to promote the combustion efficiency and facilitate discharge of the ash.
The high temperature fumes in the furnace may damage the aforesaid stirring device. Nevertheless, the stack of raw material may form a barrier separating a burning space above the raw material and an ash discharge space below the raw material, thus protecting the aforesaid stirring device in the ash discharge space. However, since an amount of the raw material for burning varies with respect to different heat energy requirements of the furnace, a height of the raw material is usually insufficient for achieving an effect of separating the high temperature fumes, so that the aforesaid stirring device is still prone to damage and has a disadvantage of short service life.
Therefore, an object of the present invention is to provide a stirring control method and a stirring control device for a combustion apparatus. The stirring control method and the stirring control device are capable of promoting service life of components in the combustion apparatus.
In one aspect of the present invention, the stirring control method for a combustion apparatus utilizes a stirring control device. The combustion apparatus includes a furnace for burning fuel material, and a stirring member rotatably disposed in the furnace for stirring the fuel material in the furnace and ash resulting from burning of the fuel material in the furnace. The stirring control method comprises:
(A) configuring the stirring control device to control rotation of the stirring member at an initial rotational speed;
(B) configuring the stirring control device to determine whether a height of the fuel material in the furnace reaches an upper detection range;
(C) configuring the stirring control device to generate a first indication when the height of the fuel material in the furnace reaches the upper detection range;
(D) configuring the stirring control device to determine whether the height of the fuel material in the furnace reaches a lower detection range when the height of the fuel material in the furnace does not reach the upper detection range; and
(E) configuring the stirring control device to control rotation of the stirring member at a first rotational speed higher than the initial rotational speed when the height of the fuel material in the furnace reaches the lower detection range.
In another aspect of the present invention, a stirring control device is for use with a combustion apparatus. The combustion apparatus includes a furnace for burning fuel material, and a stirring member rotatably disposed in the furnace for stirring the fuel material in the furnace and ash resulting from burning of the fuel material in the furnace. The stirring control device comprises an upper detector, a lower detector and a control module. The upper detector is to be disposed on the furnace for determining whether a height of the fuel material in the furnace reaches an upper detection range. The lower detector is to be disposed on the furnace for determining whether the height of the fuel material in the furnace reaches a lower detection range lower than the upper detection range. The control module is associated operably with the upper and lower detectors. The control module is configured to control generation of a first indication when the height of the fuel material in the furnace reaches the upper detection range, and to control rotation of the stirring member at a first rotational speed higher than an initial rotational speed when the height of the fuel material in the furnace reaches the lower detection range and does not reach the upper detection range.
The effect of the present invention resides in intelligently deciding rotational speed of the stirring member, and maintaining the height of the fuel material in the furnace to be within an appropriate range. In this way, the fuel material with the appropriate height may effectively separate the burning space above the fuel material and the ash discharge space below the fuel material, so as to promote the service life of the relevant components disposed in the ash discharge space.
Other features and advantages of the present invention will become apparent in the following detailed description of the preferred embodiment with reference to the accompanying drawings, of which:
Referring to
The stirring control device comprises an upper detector 2, a lower detector 3, a first temperature sensor 41, a second temperature sensor 42, a control module 5, and an indicator 6.
The upper detector 2 is to be disposed on the furnace 11 for determining whether a height of the fuel material 10 in the furnace 11 reaches an upper detection range L1. In the preferred embodiment, the upper detector 2 is a photodetector.
The lower detector 3 is to be disposed on the furnace for determining whether the height of the fuel material 10 in the furnace 11 reaches a lower detection range L2 lower than the upper detection range L1. In the preferred embodiment, the lower detector 3 is also a photodetector.
The first temperature sensor 41 is to be disposed in the furnace 11, and is adapted for detecting a burning temperature of a lower part of the fuel material 10 in the furnace 11.
The second temperature sensor 42 is to be disposed in the ash discharge space 113 on the furnace 11, and is adapted for detecting temperature of the ash, which results from burning of the fuel material 10 in the furnace 11, in the ash discharge space 113.
The control module 5 is associated operably with the upper detector 2, the lower detector 3, the first temperature sensor 41 and the second temperature sensor 42. The control module 5 is electrically coupled to the motor 121 for controlling rotational speed of the stirring member 123, and stores a preset burning temperature and a preset ash temperature.
The indicator 6 is controlled by the control module for generating a first indication and a second indication. In the preferred embodiment, the first and second indications are independently selected from at least one of an audible indication, a light indication and a text indication.
Referring to
In step 71, the combustion apparatus 1 is activated.
In step 72, the combustion apparatus 1 is configured to perform an automatic burning process.
In step 73, the control module 5 is configured to calculate an amount of the fuel material 10 required by the furnace 11 during the automatic burning process according to heat energy demand.
In step 74, the control module 5 is configured to control rotation of the stirring member 123 at an initial rotational speed V0 via the motor 121.
In step 75, the upper detector 2 is configured to make a first determination as to whether the height of the fuel material 10 piled on the tray 114 in the furnace 11 reaches the upper detection range L1.
In step 76, when a result of the first determination made in step 75 is affirmative, it means that the height of the fuel material 10 in the furnace 11 has exceeded an alert limit, i.e., flame in the furnace 11 has been extinguished such that the fuel material 10 may no longer be burned. At this time, the control module 5 is configured to control the indicator 6 to generate the first indication, and to control the combustion apparatus 1 to stop the automatic burning process.
In step 77, when the result of the first determination made in step 75 is negative, it means that the height of the fuel material 10 in the furnace 11 does not reach the alert limit, and the lower detector 3 is configured to make a second determination as to whether the height of the fuel material 10 in the furnace 11 reaches the lower detection range L2.
In step 78, when a result of the second determination made in step 77 is affirmative, it means that the height of the fuel material 10 in the furnace 11 is sufficiently high, and the control module 5 is configured to control rotation of the stirring member 123 at a first rotational speed V1 higher than the initial rotational speed V0 for a first predetermined time t1, and the flow goes back to step 73. By means of increasing rotational speed of the stirring member 123, a time required to make the ash resulting from burning of the fuel material 10 in the furnace 11 fall into the ash discharge space 113 is shortened, and the fuel material 10 in the furnace 11 is stirred with increasing frequency, such that combustion efficiency of the fuel material 10 in the furnace 11 is promoted.
It should be noted that when the lower detector 3 determines that the height of the fuel material 10 piled on the tray 114 in the furnace 11 still reaches the lower detection range L2 after step 78 has been repeated for a predetermined number of times, it means that the height of the fuel material 10 in the furnace 11 is not reduced in spite of increasing rotational speed of the stirring member 123, and there might be a malfunction of the stirring member 123. Subsequently, step 78′ is performed.
In step 78′, the control module 5 is configured to control the indicator 6 to generate the first indication which is selected from at least one of the audible indication, the light indication and the text indication.
In step 79, when the result of the second determination made in step 77 is negative, the first temperature sensor 41 is configured to detect the burning temperature of the lower part of the fuel material 10 in the furnace 11, and to transmit the burning temperature back to the control module 5.
In step 80, the control module 5 is configured to make a third determination as to whether the burning temperature of the fuel material 10 in the furnace 11 reaches the preset burning temperature.
In step 81, when a result of the third determination made in step 80 is affirmative, it means that the burning temperature of the lower part of the fuel material 10 in the furnace 11 is too high, and the control module 5 is configured to control rotation of the stirring member 123 at a second rotational speed V2 lower than the initial rotational speed V0 for a second predetermined time t2 via the motor 121, and the flow goes back to step 73.
In step 82, when the result of the third determination made in step 80 is negative, the second temperature sensor 42 is configured to detect the temperature of the ash, which results from burning of the fuel material 10 in the furnace 11, in the ash discharge space 113, and to transmit the temperature of the ash back to the control module 5.
In step 83, the control module 5 is configured to make a fourth determination as to whether the temperature of the ash, which results from burning of the fuel material 10 in the furnace 11, in the ash discharge space 113 reaches the preset ash temperature.
In step 84, when a result of the fourth determination made in step 83 is affirmative, it means that the temperature of the ash, which results from burning of the fuel material 10 in the furnace 11, in the ash discharge space 113 is too high probably because the amount of the fuel material 10 in the furnace 11 is insufficient such that a great amount of the ash and the burning fuel material 10 passes through the tray 114 and falls into the ash discharge space 113. At this time, the control module 5 is configured to control the indicator 6 to generate the second indication which is selected from at least one of the audible indication, the light indication and the text indication.
When the result of the fourth determination made in step 83 is negative, the flow goes back to step 73.
In this way, the height of the fuel material 10 in the furnace 11 may be maintained so as to effectively separate the burning space 112 above the fuel material 10 and the ash discharge space 113 below the fuel material 10 such that the stirring device 12 may be prevented from damage resulting from high temperature fumes.
It is apparent from the foregoing that the stirring control method and the stirring control device for a combustion apparatus, according to the present invention, have the following benefits and effects:
This invention is capable of intelligently controlling rotational speed of the stirring member 123 and maintaining the height of the fuel material 10 in the furnace 11 within a preferred range such that the fuel material 10 in the furnace 11 with an appropriate height may effectively separate the burning space 112 above the fuel material 10 and the ash discharge space 113 below the fuel material 10. Therefore, the stirring device 12 may be prevented from damage resulting from the high temperature fumes so as to promote service life of components in the ash discharge space 113.
While the present invention has been described in connection with what is considered the most practical and preferred embodiment, it is understood that this invention is not limited to the disclosed embodiment but is intended to cover various arrangements included within the spirit and scope of the broadest interpretation so as to encompass all such modifications and equivalent arrangements.
Number | Date | Country | Kind |
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100111582 | Apr 2011 | TW | national |