CN114383392A - Digital intelligent high-temperature drying roller for attapulgite - Google Patents

Abstract

The invention relates to the technical field of mine ore dressing equipment, in particular to an attapulgite digital intelligent high-temperature drying roller, which comprises a cement support table, a composite roller, an electromagnetic induction wire frame, a first riding wheel group, a second riding wheel group, a driving motor, a control cabinet and an infrared temperature sensor, wherein a feed inlet is arranged at the first end of the composite roller, a discharge outlet and a smoke dust moisture discharge outlet are arranged at the second end of the composite roller, the first end of the composite roller is supported on the cement support table through the first riding wheel group, the second end of the composite roller is supported on the cement support table through the second riding wheel group, the electromagnetic induction wire frame is sleeved at the first end of the composite roller, the middle part of the composite roller and the second end of the composite roller, the driving motor is arranged between the first riding wheel group and the second riding wheel group and drives the composite roller to roll, the infrared temperature sensor is arranged on the electromagnetic induction wire frame and corresponds to the outer surface of the composite roller, the electromagnetic induction wire frame, the driving motor and the infrared temperature sensor are respectively and electrically connected with the control cabinet.

Description

Digital intelligent high-temperature drying roller for attapulgite

Technical Field

The invention relates to the technical field of mine mineral processing equipment, in particular to an attapulgite digital intelligent high-temperature drying roller.

Background

In recent years, with the development of science and technology and the improvement of living standard, people have new requirements on environmental protection consciousness. The tradition uses coal, natural gas boiler to produce high-temperature gas, directly has a large amount of pollutant emissions, and operation control is inconvenient, and the cylinder heating intensifies slowly and wayward, still has the heating inequality, and a lot of heats are not absorbed by the cylinder, and the thermal efficiency is low, polluted environment, influence ore dressing quality scheduling problem.

Disclosure of Invention

Aiming at the problems, the invention provides the attapulgite digital intelligent high-temperature drying roller.

In order to achieve the purpose, the technical scheme applied by the invention is as follows:

an attapulgite digital intelligent high-temperature drying roller comprises a cement supporting table, a composite roller, an electromagnetic induction wire frame, a first riding wheel group, a second riding wheel group, a driving motor, a control cabinet and an infrared temperature sensor, wherein a feed inlet is arranged at the first end of the composite roller, a discharge outlet and a smoke dust moisture-discharging outlet are arranged at the second end of the composite roller, the first end of the composite roller is supported on the cement supporting table through the first riding wheel group, the second end of the composite roller is supported on the cement supporting table through the second riding wheel group, the electromagnetic induction wire frame is sleeved at the first end of the composite roller, the middle of the composite roller and the second end of the composite roller, the driving motor is arranged between the first riding wheel group and the second riding wheel group, and drive the compound cylinder to roll, infrared temperature sensor installs on the electromagnetic induction wire frame to correspond with compound cylinder surface, electromagnetic induction wire frame, driving motor and infrared temperature sensor electricity respectively connect in the switch board.

According to the scheme, the electromagnetic induction wire frames are supported on the cement support table through the induction wire frame support, the first end cover of the composite roller is provided with the group of electromagnetic induction wire frames, the middle cover of the composite roller is provided with the five groups of electromagnetic induction wire frames, and the second end cover of the composite roller is provided with the group of electromagnetic induction wire frames.

According to the above scheme, the electromagnetic induction wire frame comprises an induction wire frame framework, an electromagnetic induction coil and a nylon rod, the electromagnetic induction coil is limited on the induction wire frame framework through the nylon rod, and the induction wire frame framework is installed on the induction wire frame support.

According to the above scheme, response wire frame skeleton includes the stainless steel square tube, the stainless steel stick, the stainless steel ring, stainless steel flange and nylon stick fixation clamp, many stainless steel square tube fixed connection constitute the square tube support, a plurality of stainless steel rings are fixed in on the square tube support, and first stainless steel ring is fixed with the stainless steel flange respectively with last stainless steel ring, many stainless steel sticks are installed between a plurality of stainless steel rings, and all be fixed with a plurality of evenly distributed's nylon stick fixation clamp on each stainless steel ring, electromagnetic induction coil overlaps on the stainless steel stick between a plurality of stainless steel rings, nylon stick cooperation buckle is on the nylon stick fixation clamp for electromagnetic induction coil is spacing between stainless steel stick and nylon stick.

According to the scheme, the first end sleeve of the composite roller is provided with the first rolling ring, and the first rolling ring is supported on the cement support platform through the first riding wheel group.

According to the scheme, the second end sleeve of the composite roller is provided with the second rolling ring, and the second rolling ring is supported on the cement support platform through the second riding wheel group.

According to the scheme, the composite roller between the first riding wheel set and the second riding wheel set is sleeved with the driving wheel, and the driving wheel drives the composite roller to roll through the driving of the driving motor.

According to the scheme, the top of the control cabinet is provided with the audible and visual alarm indicator lamp, the cabinet door of the control cabinet is provided with the control panel, the control panel comprises a power indicator lamp, an operation indicator lamp, a starting/closing switch, an emergency stop button, an encoder and a temperature control meter, and a power distribution unit and an electromagnetic induction variable frequency power supply are arranged inside the control cabinet.

According to the scheme, the infrared temperature sensor is arranged on the electromagnetic induction wire frame through the temperature sensor support.

According to the scheme, the first end of the composite roller and the second end of the composite roller are inclined downwards.

The invention has the beneficial effects that:

1) the ideal ore dressing equipment combining the rolling of the composite roller and intelligent variable-frequency heating adopts electromagnetic induction to directly induce the rolling composite roller to ensure that the roller body uniformly heats, and no additional waste gas or waste solids are generated;

2) the high-frequency alternating electromagnetic field is used for carrying out electromagnetic induction on the composite roller, so that eddy current is generated in the roller body and is heated by the composite roller, the heat conduction path is reduced, and the heat efficiency is improved;

3) a temperature sensor is arranged in the section where each wire frame is located, PID adjustment is carried out according to the feedback of the temperature sensor and a preset program, and accurate temperature control is carried out in a subarea mode, so that closed-loop automatic control is realized;

4) the novel environment-friendly water heater is simple in structure, low in manufacturing cost and operating cost, capable of meeting the environment-friendly requirement and strong in practicability.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of an inductive wire frame support of the present invention;

FIG. 3 is a schematic diagram of an inductive wire frame of the present invention;

FIG. 4 is a schematic view of an inductive wireframe framework of the present invention;

FIG. 5 is an external schematic view of the control cabinet of the present invention;

FIG. 6 is an enlarged view of the location A in FIG. 5;

FIG. 7 is a schematic view of the interior of the control cabinet of the present invention;

FIG. 8 is a schematic diagram of the electrical connections of the inductive wireframe of the present invention;

fig. 9 is an electrical schematic diagram of the drive motor of the present invention.

1. A cement support table; 2. a composite drum; 21. a feed inlet; 22. a discharge port; 23. a smoke dust moisture-removing outlet; 3. an induction line frame; 31. an induction wire frame support; 32. an induction wire frame framework; 33. an electromagnetic induction coil; 34. a nylon rod; 35. stainless steel square tube; 36. a stainless steel rod; 37. a stainless steel ring; 38. a stainless steel flange; 39. a nylon rod fixing clamp; 4. a first riding wheel group; 41. a first rolling ring; 5. a second riding wheel group; 51. a second rolling ring; 6. a drive motor; 61. a drive wheel; 7. a control cabinet; 71. a sound-light alarm indicator light; 72. a power indicator light; 73. an operation indicator light; 74. an on/off switch; 75. an emergency stop key; 76. an encoder; 77. a temperature control meter; 78. a power distribution unit; 79. an electromagnetic induction variable frequency power supply; 8. an infrared temperature sensor; 81. a temperature sensor support.

Detailed Description

The technical solution of the present invention is described below with reference to the accompanying drawings and examples.

As shown in fig. 1 to 9, the digital intelligent attapulgite high-temperature drying roller of the invention comprises a cement support table 1, a composite roller 2, an electromagnetic induction wire frame 3, a first riding wheel group 4, a second riding wheel group 5, a driving motor 6, a control cabinet 7 and an infrared temperature sensor 8, wherein a feed inlet 21 is arranged at a first end of the composite roller 2, a discharge outlet 22 and a smoke dust moisture discharge outlet 23 are arranged at a second end of the composite roller 2, the first end of the composite roller 2 is supported on the cement support table 1 through the first riding wheel group 4, the second end of the composite roller 2 is supported on the cement support table 1 through the second riding wheel group 5, the electromagnetic induction wire frame 3 is sleeved at the first end of the composite roller 2, the middle part of the composite roller 2 and the second end of the composite roller 2, the driving motor 6 is arranged between the first riding wheel group 4 and the second riding wheel group 5 and drives the composite roller 2 to roll, infrared temperature sensor 8 installs on electromagnetic induction wire frame 3 to correspond with compound cylinder 2 surface, electromagnetic induction wire frame 3, driving motor 6 and infrared temperature sensor 8 electricity respectively connect in switch board 7. The above constitutes the basic structure of the present invention.

The invention adopts the structure, the implementation process comprises the steps of firstly starting the electromagnetic induction wire frame 3 to heat the composite roller 2, maintaining the constant temperature after the composite roller 2 reaches the preset target temperature, then starting the driving motor 6 to drive the composite roller 2 to roll, simultaneously putting the mineral powder and related materials into the composite roller from the feeding hole 21, heating and reacting the mineral powder mixed materials in the rolling process of the composite roller 2, continuously rolling and advancing towards the discharging hole 22, finally releasing the materials from the discharging hole 22 to a conveying belt of the next process to be conveyed out, facilitating the treatment of the next process, wherein the generated dust and moisture are extracted from the smoke dust moisture exhaust outlet 23, uniformly collecting and purifying, avoiding polluting the environment and meeting the requirement of environmental protection.

In practical application, according to the control requirement of the mineral aggregate production process, the temperature of each area (namely the heating temperature of the first end of the composite roller 2, the middle part of the composite roller 2 and the second end of the composite roller 2) and the rotating speed of the composite roller 2 (namely the rotating speed of the driving motor 6 for driving the composite roller 2 to roll) are set, so that mineral powder mixed materials automatically complete the mineral separation process, and the precision of mineral powder with specific components is improved.

It should be noted that, the digital intelligent attapulgite high-temperature drying roller adopts a magnetic field induction eddy current heating principle, and utilizes a high-frequency current to generate an alternating magnetic field through a coil, when magnetic lines of force in the magnetic field pass through a magnetic conduction device (the composite roller 2), countless eddy currents are generated at once, so that the composite roller 2 generates heat at a high speed, materials in the composite roller 2 are heated in a rolling manner, a heat conduction path is reduced, and the heat efficiency is improved.

In this embodiment, electromagnetic induction wire frame 3 supports on cement brace table 1 through response wire frame support 31, and the first pot head of compound cylinder 2 is equipped with a set of electromagnetic induction wire frame 3, and the middle part cover of compound cylinder 2 is equipped with five sets of electromagnetic induction wire frames 3, and the second pot head of compound cylinder 2 is equipped with a set of electromagnetic induction wire frame 3. Adopt such structure setting, a set of electromagnetic induction wireframe 3 is installed at the anterior segment of compound cylinder 2, and five sets of electromagnetic induction wireframes 3 are installed at the middle section of compound cylinder 2, and a set of electromagnetic induction wireframe 3 is installed at the back end of compound cylinder 2, and 2 sections of compound cylinder that every wireframe place all are provided with infrared temperature sensor 8 and are used for testing the barrel wall temperature of compound cylinder 2.

In this embodiment, the electromagnetic induction wire frame 3 includes an induction wire frame framework 32, an electromagnetic induction coil 33 and a nylon rod 34, the electromagnetic induction coil 33 is limited on the induction wire frame framework 32 through the nylon rod 34, and the induction wire frame framework 32 is installed on the induction wire frame support 31. By adopting the structure, the electromagnetic induction wire frame 3 is formed by combining the induction wire frame framework 32, the electromagnetic induction coil 33 and the nylon rod 34, and the electromagnetic induction wire frame is simple in structure and low in cost.

In this embodiment, the induction wire frame framework 32 includes a stainless steel square tube 35, stainless steel rods 36, stainless steel rings 37, stainless steel flanges 38 and nylon rod fixing clips 39, the plurality of stainless steel square tubes 35 are fixedly connected to form a square tube support, the plurality of stainless steel rings 37 are fixed on the square tube support, the stainless steel flanges 38 are respectively fixed on the first stainless steel ring 37 and the last stainless steel ring 37, the plurality of stainless steel rods 36 are installed between the plurality of stainless steel rings 37, each stainless steel ring 37 is fixed with a plurality of uniformly distributed nylon rod fixing clips 39, the electromagnetic induction coil 33 is sleeved on the stainless steel rods 36 between the plurality of stainless steel rings 37, and the nylon rods 34 are buckled on the nylon rod fixing clips 39 in a matching manner, so that the electromagnetic induction coil 33 is limited between the stainless steel rods 36 and the nylon rods 34. By adopting the structure, the electromagnetic induction coil 33 is limited between the stainless steel bar 36 and the nylon bar 34, on one hand, the electromagnetic induction magnetizing composite roller 2 can generate heat, and on the other hand, the electromagnetic induction coil 33 can be positioned and protected.

In this embodiment, the first end cap of the composite roller 2 is provided with a first rolling ring 41, the first rolling ring 41 is supported on the cement support platform 1 through the first riding wheel set 4, the second end cap of the composite roller 2 is provided with a second rolling ring 51, and the second rolling ring 51 is supported on the cement support platform 1 through the second riding wheel set 5. By adopting the structure, the weight of the composite roller 2 and the internal materials can be supported on one hand through the matching between the riding wheel set and the rolling ring, and on the other hand, the composite roller 2 is passively rotated along with the composite roller 2, so that the composite roller 2 is balanced and stable in the rolling process, namely, the first rolling ring 41 can play a role in assisting rolling.

In this embodiment, a driving wheel 61 is sleeved on the composite roller 2 between the first idler pulley group 4 and the second idler pulley group 5, and the driving wheel 61 drives the composite roller 2 to roll through the driving motor 6. By adopting the structure, the driving wheel 61 is driven by the driving motor 6 to drive the composite roller 2 to roll, so that the composite roller 2 drives the material to roll and heat, and the material is heated more uniformly.

In this embodiment, the top of the control cabinet 7 is provided with an audible and visual alarm indicator 71, a control panel is arranged on a cabinet door of the control cabinet 7, the control panel includes a power indicator 72, an operation indicator 73, a start/close switch 74, an emergency stop key 75, an encoder 76 and a temperature control meter 77, and a power distribution unit 78 and an electromagnetic induction variable frequency power supply 79 are arranged inside the control cabinet 7. Adopt such structure setting, can set up the rotational speed of barrel target temperature and barrel in advance of predetermineeing of every section according to different operating modes, and intelligent variable frequency power supply can be according to the difference of 8 actual measurement temperatures of infrared temperature sensor and target temperature, the electromagnetic heating power of real-time adjustment output, for example: when the calculated temperature difference value is large, the frequency and the pulse width are increased through pid adjustment, the electromagnetic induction output power is increased, the heat generated by the roller is improved, and the temperature of the roller is enabled to approach the target temperature as soon as possible.

In this embodiment, the infrared temperature sensor 8 is mounted on the electromagnetic induction wire frame 3 through a temperature sensor support 81. By adopting the structure, the infrared temperature sensor 8 is arranged on the electromagnetic induction wire frame 3 and used for testing the temperature of the section of the cylinder body.

In this embodiment, the first end of the composite drum 2 and the second end of the composite drum 2 are inclined downwards. By adopting the structure, the materials can move forward to the discharge port 22 in the rolling process of the composite roller 2.

In practical application, since the digital intelligent high temperature drying roller of attapulgite use of throwing into after ore dressing energy-conservation transformation, traditional boiler produced hot-blast ore dressing before the contrast, the digital intelligent high temperature drying roller of attapulgite advantage summarizes as follows:

1) the attapulgite digital intelligent high-temperature drying roller consists of an electromagnetic induction variable-frequency power supply 79, an electromagnetic induction wire frame 3, an infrared temperature sensor 8, a control system, a composite roller 2 and related supports, wherein the electromagnetic induction wire frame 3 is fixed outside the roller by the supports, so that a large amount of space is saved relatively, and the utilization rate of unit area is high;

2) the attapulgite digital intelligent high-temperature drying roller directly generates heat by electromagnetic induction, reduces heat transfer loss, automatically controls temperature by PID, and has higher utilization rate than the traditional hot air generation;

3) the attapulgite digital intelligent high-temperature drying roller is used for mineral separation, the temperature rising speed is high, the average pre-production preheating time of the roller is shortened to 1/4, and the unit time yield is high; the energy saving rate reaches more than 50%, and meanwhile, the balance degree of ore particles is improved;

4) attapulgite digit intelligence high temperature stoving cylinder and traditional ore dressing heating contrast, if the same cylinder external heating, bar more than 95% of electromagnetic heating equipment thermal efficiency is more than the traditional energy-conserving about 30% of heating ore dressing.

While the embodiments of the present invention have been described, the present invention is not limited to the above-mentioned embodiments, which are only illustrative and not restrictive, and those skilled in the art can make various modifications without departing from the spirit and scope of the present invention as defined by the appended claims.

Claims (10)

1. The utility model provides an attapulgite digital intelligent high temperature drying roller which characterized in that: comprises a cement supporting table (1), a composite roller (2), an electromagnetic induction wire frame (3), a first riding wheel group (4), a second riding wheel group (5), a driving motor (6), a control cabinet (7) and an infrared temperature sensor (8), wherein a feed inlet (21) is arranged at the first end of the composite roller (2), a discharge outlet (22) and a smoke dust moisture-discharging outlet (23) are arranged at the second end of the composite roller (2), the first end of the composite roller (2) is supported on the cement supporting table (1) through the first riding wheel group (4), the second end of the composite roller (2) is supported on the cement supporting table (1) through the second riding wheel group (5), the electromagnetic induction wire frame (3) is sleeved at the first end of the composite roller (2), the middle part of the composite roller (2) and the second end of the composite roller (2), the driving motor (6) is arranged between the first riding wheel group (4) and the second riding wheel group (5), and drive compound cylinder (2) and roll, infrared temperature sensor (8) are installed on electromagnetic induction wire frame (3) to correspond with compound cylinder (2) surface, induction wire frame (3), driving motor (6) and infrared temperature sensor (8) electricity respectively connect in switch board (7).

2. The attapulgite digital intelligent high-temperature drying drum according to claim 1, characterized in that: electromagnetic induction wire frame (3) support on cement brace table (1) through response wire frame support (31), the first pot head of compound cylinder (2) is equipped with a set of electromagnetic induction wire frame (3), the middle part cover of compound cylinder (2) is equipped with five groups electromagnetic induction wire frame (3), the second pot head of compound cylinder (2) is equipped with a set of electromagnetic induction wire frame (3).

3. The attapulgite digital intelligent high-temperature drying drum according to claim 2, characterized in that: electromagnetic induction wire frame (3) are including response wire frame skeleton (32), electromagnetic induction coil (33) and nylon stick (34), electromagnetic induction coil (33) are spacing on response wire frame skeleton (32) through nylon stick (34), response wire frame skeleton (32) are installed on response wire frame support (31).

4. The attapulgite digital intelligent high-temperature drying drum according to claim 3, characterized in that: the induction wire frame framework (32) comprises stainless steel square tubes (35), stainless steel rods (36), stainless steel rings (37), stainless steel flanges (38) and nylon rod fixing clamps (39), a plurality of stainless steel square tubes (35) are fixedly connected to form a square tube support, a plurality of stainless steel rings (37) are fixed on the square tube support, and the first stainless steel ring (37) and the last stainless steel ring (37) are respectively fixed with a stainless steel flange (38), a plurality of stainless steel bars (36) are arranged among the plurality of stainless steel rings (37), and a plurality of nylon rod fixing clamps (39) which are uniformly distributed are fixed on each stainless steel ring (37), the electromagnetic induction coil (33) is sleeved on the stainless steel bar (36) among the plurality of stainless steel rings (37), the nylon rod (34) is buckled on the nylon rod fixing clamp (39) in a matched mode, so that the electromagnetic induction coil (33) is limited between the stainless steel rod (36) and the nylon rod (34).

5. The attapulgite digital intelligent high-temperature drying drum according to claim 1, characterized in that: the first pot head of compound cylinder (2) is equipped with first rolling circle (41), first rolling circle (41) support on cement brace table (1) through first riding wheel group (4).

6. The attapulgite digital intelligent high-temperature drying drum according to claim 1, characterized in that: the second pot head of compound cylinder (2) is equipped with second rolling circle (51), second rolling circle (51) support on cement brace table (1) through second riding wheel group (5).

7. The attapulgite digital intelligent high-temperature drying drum according to claim 1, characterized in that: the composite roller (2) between the first riding wheel set (4) and the second riding wheel set (5) is sleeved with a driving wheel (61), and the driving wheel (61) drives the composite roller (2) to roll through a driving motor (6).

8. The attapulgite digital intelligent high-temperature drying drum according to claim 1, characterized in that: the control cabinet is characterized in that an audible and visual alarm indicator lamp (71) is arranged at the top of the control cabinet (7), a control panel is arranged on a cabinet door of the control cabinet (7), the control panel comprises a power indicator lamp (72), an operation indicator lamp (73), a start/close switch (74), an emergency stop key (75), an encoder (76) and a temperature control meter (77), and a power distribution group (78) and an electromagnetic induction variable frequency power supply (79) are arranged inside the control cabinet (7).

9. The attapulgite digital intelligent high-temperature drying drum according to claim 1, characterized in that: the infrared temperature sensor (8) is arranged on the electromagnetic induction wire frame (3) through a temperature sensor support (81).

10. The attapulgite digital intelligent high-temperature drying drum according to claim 1, characterized in that: the first end of the composite roller (2) and the second end of the composite roller (2) are inclined downwards.

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