CN106403563A - A drying system that intelligently controls the amount of coal fed according to the outlet temperature - Google Patents

Abstract

A hot air drying system, the hot air enters the drying device through the air inlet pipeline, the outlet of the drying device is provided with a temperature sensor, the temperature sensor is used for measuring the temperature of the air leaving the drying device, and the temperature sensor is in data connection with a central controller; the speed sensor measures the rotating speed of the driving motor, so that the transmission speed of the belt is calculated; the speed sensor is in data connection with the central controller; the central controller automatically adjusts the rotational speed of the drive motor, and thus the transmission speed of the pulley, based on the measured temperature of the air at the outlet of the drying device. The invention firstly connects the exhaust temperature and the coal feeding amount of the drying device, establishes the intelligent control relation between the exhaust temperature and the coal feeding amount, and intelligently utilizes solar energy to dry coal, thereby saving energy and being green and environment-friendly.

Description

A drying system that intelligently controls the amount of coal fed according to the outlet temperature

technical field

The invention belongs to the field of drying, in particular to a device and method for drying coal.

Background technique

Coal is one of the main primary energy sources in the country. However, due to the characteristics of high moisture content, low calorific value, and easy spontaneous combustion, the large-scale development and utilization of coal are greatly restricted. Whether it is from the perspective of the country's overall environment or from the perspective of corporate economic benefits, it is very important to research and promote the technology of coal drying and dehydration to increase the calorific value of coal per unit mass. The steam tube rotary coal pre-drying system, after drying the wet coal with high moisture content in the steam tube rotary dryer, it is sent to the pulverizing system equipped with a medium-speed coal mill for grinding, and then burned in the boiler. Since most of the water in the coal is evaporated, the low calorific value per unit mass of coal is improved, and the flue gas volume and exhaust loss of the boiler are also reduced. The steam in the coal is carried out by circulating the carrier gas, and the heat and water are recovered by the cooling tower and heat exchanger, and the actual water consumption of the unit is greatly reduced. Due to the high water content of coal, the drying capacity of the pulverizing system is high; and the volatile content is high, and the coal powder is prone to spontaneous combustion and explosion.

Research on coal dehydration and upgrading technology has begun to become a hot topic at home and abroad. A lot of research has been done abroad. There are many coal dehydration and upgrading technologies, which can be roughly divided into three categories: mechanical dehydration, evaporative dehydration and non-evaporative dehydration. Law. Mechanical dehydration has been widely used in coal preparation plants, but its processing capacity and dehydration efficiency are still difficult to meet the requirements. The evaporative dehydration method uses hot oil, hot air, superheated steam and other media to directly or indirectly heat the coal, so that the moisture in the coal is removed in gaseous form. The evaporative dehydration process requires a lot of energy to evaporate water, which consumes a lot of energy. The non-evaporative dehydration method is mainly divided into hydrothermal treatment method and mechanical hot press dehydration method, which removes the moisture in the coal in liquid form. The non-evaporative dehydration method has complicated process and high cost, and has not been put into industrial application at present. In addition, the non-evaporative dehydration method also brings problems such as wastewater and waste gas treatment.

The current drying equipment is not highly intelligent, and sometimes because the amount of hot air supplied or the amount of coal is too much or too little, the drying effect is not good or the waste caused by too much hot air is urgently needed. To develop a green coal dehydration technology with less energy consumption, less emission, lower cost, safety, reliability and intelligent control.

Contents of the invention

Aiming at the shortcomings of the current prior art, the purpose of the present invention is to provide a new intelligently controlled solar coal drying device to solve the above-mentioned shortcomings.

In order to achieve the above object, the technical solution of the present invention is as follows: a hot air drying system, the drying system includes a coal feeder, a crushing device and a drying device, and the coal feeder includes a coal falling hole, a speed sensor, a roller and a drive The motor and the belt drive the motor to drive the rollers and drive the belt to rotate. The coal enters from the opening of the coal fall, and enters the crushing device after being transported by the belt. The crushed coal enters the drying device from the crushing device;

Hot air enters the drying device through the air intake pipe, and the outlet of the drying device is provided with a temperature sensor, which is used to measure the temperature of the air leaving the drying device, and the temperature sensor is connected to the central controller for data;

The system includes a speed sensor, the speed sensor measures the rotation speed of the driving motor, thereby calculating the transmission speed of the belt; the speed sensor is connected with the central controller for data;

The central controller automatically adjusts the rotation speed of the drive motor according to the measured air temperature at the outlet of the drying device, thereby adjusting the transmission speed of the pulley.

As preferably, if the air temperature at the outlet of the drying device measured by the central controller decreases, the central controller automatically reduces the rotating speed of the drive motor; if the air temperature at the outlet of the drying device measured by the central controller increases, the central controller automatically increases The speed of the drive motor.

Preferably, when the measured temperature is a first temperature, the drive motor rotates at a first speed; when the measured temperature is a second temperature lower than the first temperature, the drive motor rotates at a second speed lower than the first speed Rotate; when the measured temperature is a third temperature lower than the second temperature, the drive motor rotates at a third speed lower than the second speed; when the measured temperature is a fourth temperature lower than the third temperature, The driving motor rotates at a fourth rotational speed lower than the third rotational speed; when the measured temperature is a fifth temperature lower than the fourth temperature, the driving motor rotates at a fifth rotational speed lower than the fourth rotational speed.

Preferably, the first temperature is 3-5 degrees Celsius higher than the second temperature, the second temperature is 3-5 degrees Celsius higher than the third temperature, the third temperature is 3-5 degrees Celsius higher than the fourth temperature, and the fourth temperature is 3-5 degrees Celsius higher than the fifth temperature .

Preferably, the fifth temperature is 4.5-5 degrees Celsius lower than the fourth temperature, the fourth temperature is 4-4.5 degrees Celsius lower than the third temperature, the third temperature is 3.5-4 degrees Celsius lower than the second temperature, and the second temperature is 3-3.5 degrees Celsius lower than the fifth temperature. .

Preferably, the fifth rotating speed is 0.82-0.94 times of the fourth rotating speed, the fourth rotating speed is 0.82-0.94 times of the third rotating speed, the third rotating speed is 0.82-0.94 times of the second rotating speed, and the second rotating speed is 0.82-0.94 times of the first rotating speed. 0.82-0.94 times.

Preferably, the fifth rotating speed is 0.82-0.84 times of the fourth rotating speed, the fourth rotating speed is 0.84-0.88 times of the third rotating speed, the third rotating speed is 0.88-0.91 times of the second rotating speed, and the second rotating speed is 0.88-0.91 times of the first rotating speed. 0.91-0.94 times.

As preferably, it includes a solar heat collector, the air enters the solar heat collector through an induced draft fan, and absorbs the heat of the solar heat collector at the solar heat collector to form hot air, and the hot air enters the drying machine under the guidance of the fan. device for drying coal.

As a preference, part of the hot air heated by the solar collector enters the drying device through the main passage, and part of it enters the heat utilization device through the bypass passage. The first fan is arranged on the main passage connecting the solar collector to the drying device. A second fan is arranged on the bypass passage connected to the heat utilization device, and the flow of hot air entering the drying device and the heat utilization device is changed by changing the power of the first fan and the second fan.

As preferably, the drying device includes a box body and a conveyor belt, the conveyor belt passes through the box body, the hot air enters the drying device from the lower part of the drying device, then passes through the conveyor belt to dry the coal transported on the conveyor belt, and finally passes through the drying device The outlet is discharged, thereby completing the drying of the coal;

The air intake pipe of the drying device includes a main pipe, and the main pipe is connected with a plurality of distribution pipes, and the air is transported to the lower part of the conveyor belt through the distribution pipes, and a plurality of distribution pipes are arranged along the conveying direction of the conveyor belt, and a fan is arranged on each distribution pipe , along the conveying direction of the conveyor belt, the power of the fan becomes smaller and smaller, and the power reduction range of the fan gradually decreases.

As a preference, when the coal mass per unit time entering the conveyor belt is Z and the mass moisture content is H, the temperature of the hot air entering the air inlet pipeline of the drying device is D1, the air flow rate is L, and the temperature of the hot air leaving the outlet of the drying device is D2, when the transmission speed of the conveyor belt is S, it means that the drying effect meets certain conditions; the above-mentioned unit time coal mass Z, mass moisture content H, air inlet pipe air temperature D1, air flow L, outlet air temperature D2, conveyor belt Transmission speed S is called standard quality, standard water content, standard inlet pipe temperature, standard outlet temperature, standard air flow, standard speed, that is, standard data; the standard data is stored in the central controller;

When the coal mass per unit time is z and the mass moisture content is h, the air flow rate l entering the drying equipment, the air temperature d1 of the inlet pipe, the outlet air temperature d2 and the conveying speed s of the conveyor belt meet the following operating modes:

The transmission speed s of the conveyor belt keeps the standard speed S unchanged, and the air flow rate l changes as follows:

l*(d1-d2)=L*(D1-D2)*(h/H) ^a *(z/Z) ^b , where a and b are parameters, 1.09<a<1.15, 1.08<b<1.16; as Preferably, b gradually increases with the increase of h/H, and b gradually increases with the increase of z/Z.

Compared with the prior art, the drying device of the present invention has the following advantages:

1) The present invention connects the exhaust temperature of the drying device with the coal supply for the first time, and establishes an intelligent control relationship between the two. At the same time, the intelligent use of solar energy is used to dry coal, which saves energy and is environmentally friendly.

2) The central controller automatically controls the amount of hot air sent to the drying device and/or the speed of the conveyor belt to save energy.

3) By controlling the air volume along the direction of the conveyor belt, the drying efficiency is greatly improved and the best drying effect is guaranteed.

4) Through a large number of researches, the optimal control relationship for controlling the amount of hot air and the transmission speed is obtained, which realizes intelligent drying control and reduces human intervention.

Description of drawings

Fig. 1 is a structural schematic diagram of an embodiment of a coal drying device of the present invention.

Fig. 2 is a structural schematic diagram of another embodiment of the coal drying device of the present invention. Fig. 3 is a schematic diagram of the preferred control of the coal drying device of the present invention.

Fig. 3 is a schematic flow chart of the coal drying device of the present invention.

Fig. 4 is a schematic diagram of the solar coal drying device of the present invention.

Fig. 5 is a schematic diagram of another embodiment of the solar coal drying device of the present invention.

Fig. 6 is a schematic diagram of the control system of the drying device of the present invention.

Among them, coal feeder 1, crushing device 2, air intake pipe 3, drying area 4, main channel 5, conveyor belt 6, pulley 7, coal bunker 8, air outlet 10 in drying area, air outlet 11, bypass channel 12, fan 13. Outlet temperature sensor 14, heat collector 15, induced draft fan 16, drying device 17, heat exchange device 18, main road valve 19, bypass valve 20, central controller 21, intake pipe temperature sensor 22, flow meter 23 , header 24

detailed description

Fig. 1-2 has shown the structural representation of drying system, as shown in Fig. 1, described drying system comprises coal feeder 1, crushing device 2, drying device 17, and described drying device 17 comprises box body, temperature sensor, flow rate sensor , central controller 21 and conveyer belt 6, described conveyer belt 6 passes casing, and temperature sensor comprises inlet temperature sensor 22 and outlet temperature sensor 14, measures the hot air temperature entering drying device 17 and the air temperature leaving drying device 17 respectively, The flow rate sensor 23 is used to measure the air flow rate entering the drying device 17 , thereby calculating the air flow rate entering the drying device 17 . The inlet temperature sensor 22 , outlet temperature sensor 14 and flow rate sensor 23 are connected to the central controller 21 .

Preferably, the hot air enters the drying device through the air inlet pipe 3 , and the inlet temperature sensor 22 is arranged in the air inlet pipe 3 .

The coal enters from the coal fall port 1-1, and is transported by the belt 1-7 into the crushing device 2. After the crushing device 2 crushes the coal, the coal is transported to the drying device 17, and then passes through the belt with holes in the drying device. The type conveying equipment is connected to the coal bunker 8 after passing through the drying device box successively.

The air enters the drying device 17 from the bottom of the drying device 17, then passes through the conveyor belt 6 to dry the coal transported on the conveyor belt 6, and finally discharges from the outlet of the drying device 17, thereby completing the drying of the coal.

As shown in Figures 1 and 2, the coal feeder 1 is a belt-type load-bearing coal feeder, which includes a coal drop hole 1-1, a load-bearing roller 1-2, a weight sensor 1-3, a speed sensor 1-4, Roller 1-5 and driving motor 1-6, belt 1-7, driving motor 1-6 drives roller 1-5 to rotate, and drives belt 1-7 to rotate, and described speed sensor 1-4 measures the speed of driving motor 1-6 Speed, so as to calculate the transmission speed of the belt. The load-bearing roller 1-2 is arranged on the lower part of the belt 1-7 and tightly supports the belt, and the weight sensor 1-3 is installed on the lower part of the load-bearing roller 1-2, and is used to measure the weight transported by the belt 1-7 per unit time. coal quality. Described speed sensor 1-4, weight sensor 1-3 are connected with central controller 21 data.

As shown in Figure 6, the hot air enters the drying device 17 through the air intake pipe 3, and the central controller 21 automatically adjusts the rotating speed of the drive motor 1-6 according to the temperature of the air at the outlet of the drying device 17 measured, thereby adjusting the pulley transmission speed.

The outlet temperature of the drying device is kept constant by controlling the rotating speed, so as to avoid heat loss caused by too much hot air and poor drying effect of coal caused by too little hot air. Energy can be saved and the best drying effect can be guaranteed by controlling the coal feeding amount of the coal feeder.

As preferably, if the discharge air temperature of the drying device 17 measured by the central controller 21 reduces, then the central controller 21 automatically reduces the rotating speed of the drive motor 1-6; if the discharge air temperature of the drying device 17 measured by the central controller 21 Raise, then the central controller automatically raises the rotating speed of drive motor 1-6.

The rotating speed of the motors 1-6 is controlled by automatically detecting the exhaust temperature of the drying device, thereby controlling the quality of the coal entering the drying device to ensure that the coal entering the drying device 17 reaches an appropriate amount. If there is too much coal, the drying effect will be too poor, and if there is too little coal, it will cause waste of hot air.

In operation, when the measured temperature is the first temperature, the drive motor 1-6 rotates at the first rotating speed; when the measured temperature drops to a second temperature lower than the first temperature, the drive motor 1-6 rotates at a speed lower than The second rotating speed of the first rotating speed rotates; When the measured temperature drops to a third temperature lower than the second temperature, the drive motor 1-6 rotates at a third rotating speed lower than the second rotating speed; when the measured temperature decreases When reaching a fourth temperature lower than the third temperature, the drive motor 1-6 rotates at a fourth speed lower than the third speed; when the measured temperature drops to a fifth temperature lower than the fourth temperature, the drive motor 1 -6 rotates at a fifth rotational speed lower than the fourth rotational speed.

Preferably, the first temperature is 3-5 degrees Celsius higher than the second temperature, the second temperature is 3-5 degrees Celsius higher than the third temperature, the third temperature is 3-5 degrees Celsius higher than the fourth temperature, and the fourth temperature is 3-5 degrees Celsius higher than the fifth temperature .

Preferably, the fifth temperature is 4.5-5 degrees Celsius lower than the fourth temperature, the fourth temperature is 4-4.5 degrees Celsius lower than the third temperature, the third temperature is 3.5-4 degrees Celsius lower than the second temperature, and the second temperature is 3-3.5 degrees Celsius lower than the fifth temperature. .

Preferably, the fifth rotating speed is 0.82-0.94 times of the fourth rotating speed, the fourth rotating speed is 0.82-0.94 times of the third rotating speed, the third rotating speed is 0.82-0.94 times of the second rotating speed, and the second rotating speed is 0.82-0.94 times of the first rotating speed. 0.82-0.94 times.

Preferably, the fifth rotating speed is 0.82-0.84 times of the fourth rotating speed, the fourth rotating speed is 0.84-0.88 times of the third rotating speed, the third rotating speed is 0.88-0.91 times of the second rotating speed, and the second rotating speed is 0.88-0.91 times of the first rotating speed. 0.91-0.94 times.

By optimizing the above temperature and motor speed, especially by setting differentiated motor speed and temperature difference, the drying efficiency can be further improved and time can be saved. It is found through experiments that the drying efficiency can be increased by about 11-15%.

Fig. 4 shows a kind of solar coal drying system, comprises solar thermal collector 15 and above-mentioned drying device 17, and described air enters solar thermal collector 15 by induced draft fan 16, and absorbs the heat of solar energy in solar thermal collector 15, Hot air is formed, and the hot air enters the drying device under the guidance of the fan 19 to dry the coal.

As a preference, Fig. 5 shows a schematic diagram of another embodiment of the solar coal drying device of the present invention.

As shown in Figure 5, a part of the hot air heated by the solar collector enters the drying device 17 through the main passage 5, and a part enters the heat utilization device 18 through the bypass passage 12, and the main passage 5 that the solar collector 15 is connected to the drying device 17 The first blower fan 19 is set on the top, the solar heat collector 15 is connected with the heat utilization device 18 and the second blower fan 20 is set on the bypass channel 12, and the change of the power of the first blower blower 19 and the second blower blower 20 changes into the drying device 17 and heat Utilize the hot air flow of the device 18.

Preferably, the conveyor belt 6 is provided with a speed control unit, and the speed control unit is in data connection with the central controller 21, and the central controller 21 controls the speed of the conveyor belt 6 through the speed control unit.

Preferably, the speed control part includes a speed detection part, and the speed detection part transmits the detected data of the conveyor belt 6 to the central controller 21, and the central controller 21 adjusts the power of the motor of the conveyor belt 6 according to the detected data. If the detected speed is lower than the data calculated by the central controller 21, the power of the motor is increased, otherwise, the power of the motor is decreased. Preferably, the transmission speed of the transmission belt 6 is adjusted by controlling the rotation speed of the transmission wheel 9 by a motor.

Preferably, the box body is a cavity with a trapezoidal cross section, electric doors are provided at the entrance and exit, and the opening of the electric doors can be adjusted in the up and down direction. The central controller 21 automatically adjusts the opening of the electric door according to the coal seam thickness of the input coal to prevent energy loss caused by excessive opening and achieve the purpose of saving energy.

Preferably, the thickness of the coal seam is automatically detected by a thickness detection device, which is connected to a programmable automatic controller, and the thickness detector transmits the thickness data of the coal seam to the central controller 21 . The main advantage of using the thickness detection device is to automatically obtain the thickness data of the coal seam, avoiding the cumbersome procedures of manually inputting the thickness data, and improving the efficiency and accuracy of drying.

Preferably, the thickness detection device is arranged near the entrance of the drying device 17 , for example, at the entrance of the drying device 17 , and/or on a bracket outside the drying device 17 at a certain distance from the entrance of the drying device 17 . It is also possible to calculate the average thickness by setting thickness detection devices at different positions and measuring the thickness multiple times.

Preferably, the thickness detection device includes an infrared emitter and an infrared receiver. The infrared emitter emits infrared rays to measure the thickness of the plate, and the infrared receiver receives the thickness data sent by the infrared emitter and transmits the thickness data to the central controller 21 .

Preferably, the infrared emitter includes a first infrared emitting unit, a second infrared emitting unit, and a third infrared emitting unit placed equidistantly horizontally; the infrared receiver includes a first infrared receiving unit, a second infrared receiving unit placed equidistantly horizontally and the third infrared receiving unit, the first infrared receiving unit, the second infrared receiving unit and the third infrared receiving unit and the first infrared transmitting unit, the second infrared transmitting unit and the third infrared transmitting unit respectively receive the first infrared transmitting unit, Infrared rays emitted by the second infrared emitting unit and the third infrared emitting unit. By setting multiple infrared emitting units and infrared receiving units, multiple measurements can be performed to ensure the accuracy of the data. At the same time, when part of the infrared emitting unit and the infrared receiving unit are damaged, the measurement of the plate thickness will not be affected.

Preferably, the infrared emitting unit is arranged on the bracket across the transmission belt at a certain distance from the entrance, the infrared receiving unit is arranged on the entrance position of the drying device 17, the first infrared receiving unit, the second infrared receiving unit and the third infrared receiving unit The units correspond horizontally to the first infrared emitting unit, the second infrared emitting unit and the third infrared emitting unit respectively.

Preferably, the infrared receiving unit is arranged on the support across the transmission belt at a certain distance from the entrance, the infrared emitting unit is arranged on the entrance position of the drying device 17, the first infrared receiving unit, the second infrared receiving unit and the third infrared receiving unit The units correspond horizontally to the first infrared emitting unit, the second infrared emitting unit and the third infrared emitting unit respectively.

Preferably, the transmission speed of the conveyor belt 6 is 0.6-0.8m/s.

Preferably, a drying zone 4 is set in the box, and along the conveying direction of the conveyor belt 6, the distribution of air flow in the drying zone 4 decreases gradually. In this way, as the moisture content of the coal gradually decreases, less and less air is needed, thereby saving energy.

Preferably, along the conveying direction of the conveyor belt 6, the air flow rate of the drying zone 4 decreases gradually. If the flow S is set as a function of the distance x from the entrance of the drying zone 4, S=l(x), then in the drying zone 4, 1'(x)<0, 1"(x)<0, wherein l'( x), l"(x) are the first and second derivatives of l(x), respectively.

Experiments show that through the change of the air flow rate and the change of the increase rate, the best effect of coal drying can be achieved, and energy can also be saved. Compared with the same air flow distribution, the drying effect can be increased by 15-20%, that is, energy can be saved by 15-20%.

Preferably, the change of the flow rate of the air is realized in the following manner. Wherein mode one is to set header 24 at the bottom of conveyor belt 6, as shown in Figure 1, the top of described header 24 is provided with holes, and air is transported through the holes on header 24 to dry coal.

Preferably, in the drying zone 4, along the conveying direction of the conveyor belt 6, the distribution density of the holes becomes smaller and smaller, and preferably, the distribution density of the holes decreases gradually. Preferably, the maximum density is 1.2-1.3 times the minimum density.

By changing the density of the above-mentioned holes, the air flow rate can be changed along the conveying direction of the conveyor belt 6 .

Preferably, the change of the air flow can also be realized through the change of the hole diameter. Preferably, in the drying zone 4 , along the conveying direction of the conveyor belt 6 , the diameter of the holes becomes smaller and smaller, and preferably, the diameter of the holes becomes smaller gradually. Preferably, the largest pore diameter is 1.2-1.3 times the smallest pore diameter.

Preferably, the holes are round holes.

Preferably, the air flow rate can be changed by changing the power of the fan, as shown in FIG. 2 .

The air intake pipe of the drying device 17 is provided with a main pipe, and then many shunt pipes are set through the main pipe, and the air is transported to the lower part of the conveyor belt 6 by the shunt pipes, and a plurality of shunt pipes are set along the conveying direction of the conveyor belt 6, and each shunt pipe is provided with A fan 13 , as shown in FIG. 6 , realizes the distribution of flow along the conveying direction of the conveyor belt 6 by changing the power of the fan.

Preferably, in the drying area 4, along the conveying direction of the conveyor belt 6, the power of the fan 13 becomes smaller and smaller, and preferably, the power of the fan 13 decreases gradually. Preferably, the maximum power is 1.2-1.3 times of the minimum power.

Preferably, the air inlet temperature sensor is arranged on the main pipe of the air inlet pipe.

Preferably, the fan 13 is connected to the central controller 21 in data, and the power of the fan can be adjusted through the central controller 21 .

The air intake duct fan 19 is arranged on the main pipe of the air intake duct, and the air intake duct fan 19 is connected with the data of the central controller 21, and the central controller 21 adjusts the total heat entering the drying device 17 by adjusting the power of the fan 19. air volume.

In the actual working process, there needs to be an optimal relationship between the speed of the conveyor belt 6 and the flow temperature of the air. If the speed of the conveyor belt 6 is too fast, the drying time will be short, which will affect the drying quality. If the speed of the conveyor belt 6 is too slow , If the drying time is long, too much energy may be wasted and the efficiency will be reduced. Similarly, if the air flow and temperature are too low, the drying quality will be affected, and if the flow and temperature are too high, too much energy will be wasted. Therefore, through a large number of experiments, the best relationship between air flow, air temperature and transmission speed has been obtained.

The drying device 17 can automatically adjust the air flow rate and the conveying speed of the conveyor belt 6 according to the moisture content of the dry coal. The control method is as follows: Assuming that the coal quality per unit time from the crushing device to the conveyor belt 6 is Z and the mass moisture content is H, the air temperature of the intake pipe entering the drying device 17 is D1, and the air flow rate is L, leaving the drying device 17 When the outlet air temperature is D2 and the transmission speed of the conveyor belt 6 is S, it means that the drying effect meets certain conditions. The above-mentioned unit time coal quality Z, mass water content H, air intake pipe temperature D1, air flow L, outlet air temperature D2, and transmission speed S of conveyor belt 6 are called standard quality, standard water content, standard air intake pipe temperature, Standard outlet temperature, standard air flow, standard speed, that is, standard data. The standard data is stored in the central controller 21 .

The standard data represent the data of the drying effect satisfying certain conditions. For example, it may meet a certain drying effect, for example, the drying effect is that the moisture content of coal is 0.04%, or when a certain drying effect is achieved, the energy consumption is the least. Of course, the preferred condition is that when a certain drying effect is achieved, the data that consumes the least energy is used as the standard data.

The temperature and speed adjusted by the following formula can basically meet the drying effect of certain conditions achieved by the standard data.

When the coal mass per unit time is z and the mass moisture content is h, the air flow rate l entering the drying equipment, the air temperature d1 of the inlet pipe, the outlet air temperature d2 and the transmission speed s of the conveyor belt 6 satisfy the following three different operating modes one:

The first mode: the transmission speed s of the conveyor belt 6 keeps the standard speed S unchanged, and the flow rate l of the air changes as follows:

l*(d1-d2)=L*(D1-D2)*(h/H) ^a *(z/Z) ^b , wherein a, b are parameters, 1.09<a<1.15, 1.08<b<1.16; preferred Yes, a=1.12, b=1.14; preferably, a gradually increases with the increase of h/H, and b gradually increases with the increase of z/Z.

The second mode: 1 keeps the standard flow rate L unchanged, and the transmission speed s of the conveyor belt 6 changes as follows:

(S/s)*(d1-d2)=(D1-D2)*(h/H) ^c *(z/Z) ^d , where c and d are parameters, 1.08<c<1.15, 1.18<d<1.22 ; Preferably, c=1.1`, d=1.20;

The third mode: l and s are variable, and the relationship between the air flow and the transmission speed of the conveyor belt 6 is as follows:

(S*l*(d1-d2))/(s*L*(D1-D2))＝g*(h/H) ^e *(z/Z) ^f , where g, e, f are parameters, g Satisfies the following formula:

(S*l*(d1-d2))/(s*L*(D1-D2))>1, 0.92<g<0.97; preferably, g=0.95;

(S*l*(d1-d2))/(s*L*(D1-D2))<1, 1.03<g<1.06; preferably, g=1.05;

(S*l*(d1-d2))/(s*L*(D1-D2))=1, 0.97<g<1.03; preferably, g=1;

Preferably, the third mode selects a group of l and s with the smallest value of ((1-l/L) ² +(1-s/S) ² ); of course, the first group of l and s that meets the requirements can also be selected, A group can also be randomly selected from l and s that meet the conditions;

1.08<e<1.13, 1.14<f<1.18; preferably, e=1.10, f=1.16.

The formulas of the above three modes need to meet the following conditions: 0.9<l/L<1.1, 0.9<s/S<1.1.

The above-mentioned formula has been verified by a large number of actual conditions, and fully meets the needs of actual drying of coal.

In practical applications, multiple sets of standard data are stored in the central controller 21, and then the central controller 21 according to the data input by the user (the amount of coal per unit time and the moisture content of the coal), satisfies 0.9<s/S<1.1, 0.9< In the case of 1/L<1.1, the appropriate standard data is automatically selected as the basis.

Preferably, when two or more sets of standard data appear, an interface for standard data selected by the user can be provided. Preferably, the system can automatically select ((1-1/L) ² +(1-s/S) ² ) with the smallest value.

Only one of the three modes can be stored in the central controller 21 , or two or three can be stored in the central controller 21 .

In the previous formula, d1 and d2 are obtained through real-time detection by the temperature sensor, and obtained through the temperature sensors 14 and 22; the mass moisture content h is detected by manual input in advance, and the coal quality z can be measured by the weight sensor. At this time, the central controller 21 detects the transmission speed of the conveyor belt 6 .

Preferably, when adjusting the air flow, the fan power of all the drying zones 4 adopts the same increase or decrease, for example, all increase by 10% at the same time.

Preferably, when the air flow is adjusted, all the fan powers in the drying zone 4 adopt different increases or decreases. Along with the conveying direction of the conveyor belt 6, the range of increase or decrease of the fan power in the drying zone 4 gradually decreases, for example, Along the transmission direction of the conveyor belt 6, the fan power in the front increases by 15%, and the fan power in the back increases by 12%, 11%, and so on.

In the previous formula, the air flow rate is the total air flow rate entering the drying equipment. Preferably, the flow detection device 23 is arranged on the main pipe of the intake pipe.

The invention also discloses a method for realizing the intelligent operation of the drying equipment, which includes the following steps:

1) First, store one or more sets of standard data in the central controller 21: the coal quality per unit time is Z, the mass moisture content is H, the air temperature of the intake pipe is D1, the air flow rate is L, the outlet air temperature is D2, and the conveyor belt 6 The transmission speed S:

2) Input the coal unit mass and water content on the operation interface; of course, the coal mass per unit time can be automatically detected by the central controller 21;

3) The central controller 21, according to the input coal unit mass and water content, the user chooses to execute or automatically executes (for example, in the case of only one operating mode) one of the following three modes:

The first mode: the transmission speed s of the conveyor belt 6 keeps the standard speed S unchanged, and the flow rate l of the air changes as follows:

l*(d1-d2)=L*(D1-D2)*(h/H) ^a *(z/Z) ^b , wherein a, b are parameters, 1.09<a<1.15, 1.08<b<1.16; preferred , a=1.12, b=1.14;

The second mode: l keeps the standard flow rate L unchanged, and the transmission speed s of the conveyor belt 6 changes as follows:

(S/s)*(d1-d2)=(D1-D2)*(h/H) ^c *(z/Z) ^d , where c and d are parameters, 1.08<c<1.15, 1.18<d<1.22 ; Preferably, c=1.1`, d=1.20

The third mode: l and s are variable, and the relationship between the air flow and the transmission speed of the conveyor belt 6 is as follows:

(S*l*(d1-d2))/(s*L*(D1-D2))＝g*(h/H) ^e *(z/Z) ¹ , where g, e, l are parameters, g Satisfies the following formula:

(S*l*(d1-d2))/(s*L*(D1-D2))>1, 0.92<g<0.97; preferably, g=0.95;

(S*l*(d1-d2))/(s*L*(D1-D2))<1, 1.03<g<1.06; preferably, g=1.05;

(S*l*(d1-d2))/(s*L*(D1-D2))=1, 0.97<g<1.03; preferably, g=1;

Preferably, the third mode selects a group of l and s with the smallest value of ((1-l/L) ² +(1-s/S) ² ); of course, the first group of l and s that meets the requirements can also be selected, It is also possible to randomly select a group from l and s that meet the conditions;

1.08<e<1.13, 1.14<l<1.18; preferably, e=1.10, l=1.16.

The formulas of the above three modes need to meet the following conditions: 0.9<l/L<1.1, 0.9<s/S<1.1.

4) The drying device 17 starts drying operation.

As preferably, multiple groups of standard data are input in step 1);

Preferably, when there are two or more sets of standard data, the user can select the standard data through the user interface.

In practical applications, multiple sets of standard data are stored in the central controller 21, and then the central controller 21 is based on the data input by the user (coal quality and coal moisture content per unit time), when 0.9<s/S<1.1, 0.9<l In the case of /L<1.1, the appropriate standard data is automatically selected as the basis.

Preferably, when there are two or more sets of standard data, an interface for standard data selected by the user can be provided. Preferably, the system can automatically select ((1-l/L) ² +(1-s/S) ² ) with the smallest value.

Preferably, the hot air coming out of the drying device 17 enters the heat utilization device 18 so as to utilize the waste heat. Further preferably, the heat utilization device 18 is a boiler, and the hot air directly enters the boiler for combustion support.

Preferably, the heat utilization device 18 is a heat storage tank.

Preferably, the air coming out of the heat utilization device 18 is directly circulated into the heat collector 15 for heating.

Although the present invention has been disclosed above with preferred embodiments, the present invention is not limited thereto. Any person skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so the protection scope of the present invention should be based on the scope defined in the claims.

Although the present invention has been disclosed above with preferred embodiments, the present invention is not limited thereto. Any person skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so the protection scope of the present invention should be based on the scope defined in the claims.

Claims (10)

1. A hot air drying system, the drying system includes a coal feeder, a crushing device and a drying device, and the coal feeder includes a coal drop hole, a speed sensor, a roller and a drive motor, a belt, and the drive motor drives the roller and drives the When the belt rotates, the coal enters from the coal dropper and enters the crushing device after being transported by the belt, and the crushed coal enters the drying device from the crushing device; Hot air enters the drying device through the air intake pipe, and the outlet of the drying device is provided with a temperature sensor, which is used to measure the temperature of the air leaving the drying device, and the temperature sensor is connected to the central controller for data; The system includes a speed sensor, the speed sensor measures the rotation speed of the driving motor, thereby calculating the transmission speed of the belt; the speed sensor is connected with the central controller for data; The central controller automatically adjusts the rotation speed of the drive motor according to the measured air temperature at the outlet of the drying device, thereby adjusting the transmission speed of the pulley. 2. The drying system according to claim 1, characterized in that, if the air temperature at the outlet of the drying device measured by the central controller decreases, the central controller automatically reduces the rotating speed of the drive motor; if the outlet of the drying device measured by the central controller When the air temperature rises, the central controller will automatically increase the speed of the drive motor. 3. The drying system according to claim 2, wherein when the measured temperature is the first temperature, the drive motor rotates at the first rotational speed; when the measured temperature is the second temperature lower than the first temperature , the drive motor rotates at a second speed lower than the first speed; when the measured temperature is a third temperature lower than the second temperature, the drive motor rotates at a third speed lower than the second speed; when the measured When the temperature is a fourth temperature lower than the third temperature, the drive motor rotates at a fourth speed lower than the third speed; when the measured temperature is a fifth temperature lower than the fourth temperature, the drive motor rotates at a speed lower than the fourth speed. The fifth of the four speeds rotates. 4. drying system as claimed in claim 3, the first temperature is greater than the second temperature 3-5 degrees Celsius, the second temperature is greater than the third temperature 3-5 degrees Celsius, the third temperature is greater than the fourth temperature 3-5 degrees Celsius, the fourth The temperature is 3-5 degrees Celsius greater than the fifth temperature. 5. The drying system according to claim 4, the fifth temperature is 4.5-5 degrees Celsius lower than the fourth temperature, the fourth temperature is 4-4.5 degrees Celsius lower than the third temperature, the third temperature is 3.5-4 degrees Celsius lower than the second temperature, and the second The temperature is 3-3.5 degrees Celsius lower than the fifth temperature. 6. The drying system according to claim 3, the fifth rotating speed is 0.82-0.94 times of the fourth rotating speed, the fourth rotating speed is 0.82-0.94 times of the third rotating speed, and the third rotating speed is 0.82-0.94 times of the second rotating speed , the second rotational speed is 0.82-0.94 times of the first rotational speed. 7. The drying system according to claim 6, the fifth rotating speed is 0.82-0.84 times of the fourth rotating speed, the fourth rotating speed is 0.84-0.88 times of the third rotating speed, and the third rotating speed is 0.88-0.91 times of the second rotating speed , the second rotational speed is 0.91-0.94 times of the first rotational speed. 8. drying system as claimed in claim 1, comprises solar thermal collector, and air enters solar thermal collector by induced draft fan, and absorbs the heat of solar thermal collector at solar thermal collector, forms hot air, and described hot air Under the guidance of the fan, it enters the drying device to dry the coal. 9. The drying system as claimed in claim 8, a part of the hot air heated by the solar collector enters the drying device through the main channel, and a part enters the heat utilization device through the bypass channel, and the solar collector is connected to the main channel of the drying device. The first fan is set, the solar heat collector is connected with the heat utilization device and the second fan is installed on the bypass channel, and the flow of hot air entering the drying device and the heat utilization device is changed by changing the power of the first fan and the second fan. 10. The solar coal drying system according to claim 1 or 2, characterized in that: the drying device includes a box body and a conveyor belt, the conveyor belt passes through the box body, and the hot air enters the drying device from the lower part of the drying device , and then pass through the conveyor belt to dry the coal transported on the conveyor belt, and finally discharge from the outlet of the drying device, thereby completing the drying of the coal; The air intake pipeline of the drying device includes a main pipe, the main pipe is connected with a plurality of shunt pipes, and the air is transported to the lower part of the conveyor belt through the shunt pipes, and a plurality of shunt pipes are arranged along the conveying direction of the conveyor belt, and a fan is arranged on each shunt pipe, Along the conveying direction of the conveyor belt, the power of the fan becomes smaller and smaller, and the power reduction range of the fan gradually decreases.