CN115682696A

CN115682696A - Energy-saving drying equipment

Info

Publication number: CN115682696A
Application number: CN202211388825.6A
Authority: CN
Inventors: 王柱
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-11-08
Filing date: 2022-11-08
Publication date: 2023-02-03

Abstract

The invention relates to the technical field of drying, in particular to energy-saving drying equipment which comprises a barrel frame and a spiral shaft rotationally connected in the barrel frame, wherein a combustion chamber is fixedly connected to the barrel frame, a water tank is fixedly connected to the combustion chamber, a fan is rotationally connected to the water tank, a transmission shaft A is rotationally connected to the left end of the barrel frame, the transmission shaft A and the fan are in transmission through a first belt, a bevel gear A is fixedly connected to the lower portion of the transmission shaft A, a transmission shaft B is rotationally connected to the barrel frame, a bevel gear B is fixedly connected to the transmission shaft B, the bevel gear B is in meshing transmission with the bevel gear A, a belt wheel A is fixedly connected to the spiral shaft, and the belt wheel A and the transmission shaft B are in transmission through a second belt. The lower extreme fixedly connected with downcomer of water tank, beneficial effect is for can not using the electric energy just can dry the material.

Description

Energy-saving drying equipment

Technical Field

The invention relates to the technical field of drying, in particular to energy-saving drying equipment.

Background

The drying equipment is mainly used for drying materials with certain humidity or granularity in the departments of mineral separation, building materials, metallurgy, chemical engineering, printing and the like. The large energy-saving dryer has strong adaptability to materials, can dry various materials, is simple and reliable in equipment operation, is widely adopted, and is widely used for drying materials such as slag limestone, coal powder, slag, clay and the like in building materials, metallurgy, chemical industry and cement industry. Most of the existing energy-saving drying equipment are installed at specific places, and then the materials are dried by using electric energy to generate heat or hot air, so that the electric energy is consumed, the drying operation can be carried out only at the specific places, and the materials cannot be dried by using the electric energy in remote mountainous areas without the electric energy.

The existing drying equipment is lack of energy-saving drying equipment, and materials can be dried without using electric energy.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides energy-saving drying equipment which can dry materials without using electric energy.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the utility model provides an energy-saving drying equipment, includes the barrel holder and rotates the screw axis of connecting in the barrel holder, fixedly connected with combustion chamber on the barrel holder, fixedly connected with water tank on the combustion chamber, the water tank internal rotation is connected with the fan, the left end of barrel holder rotates and is connected with transmission shaft A, transmission shaft A with the fan is through first belt drive, transmission shaft A below fixedly connected with bevel gear A, it is connected with transmission shaft B to rotate on the barrel holder, fixedly connected with bevel gear B on the transmission shaft B, bevel gear B with bevel gear A meshing transmission, fixedly connected with band pulley A on the screw axis, band pulley A with transmission shaft B passes through second belt drive.

The lower end of the water tank is fixedly connected with a sewer pipe, a water storage cavity A is arranged in the spiral shaft, and a water storage cavity B is arranged in the barrel frame.

The front end fixedly connected with of barrel holder draws water a section of thick bamboo, it has the pole of drawing water to draw water an internal sliding connection, the lower extreme of pole of drawing water is provided with the dish of drawing water, be provided with a plurality of check valves in the dish of drawing water, the upper end fixedly connected with water pipe of a section of thick bamboo draws water.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of an energy-saving drying apparatus according to the present invention;

FIG. 2 is a schematic structural diagram of the back of an energy-saving drying apparatus according to the present invention;

FIG. 3 is a cross-sectional view of an energy saving drying apparatus according to the present invention;

FIG. 4 is a schematic view showing the structure of the barrel holder and the screw shaft according to the present invention;

FIG. 5 is a cross-sectional view of the barrel holder and screw shaft according to the present invention;

FIG. 6 is a schematic view showing the construction of a combustion chamber and a water tank in the present invention;

FIG. 7 is a schematic structural diagram of a fan according to the present invention;

FIG. 8 is a schematic structural view of a water pumping barrel and a water pumping rod according to the present invention;

FIG. 9 is a schematic view of the structure of the water pumping rod and the water pumping frame of the present invention;

FIG. 10 is a schematic view of the structure of roller A and roller B of the present invention;

FIG. 11 is an enlarged view of a portion of the projection and recess of the present invention;

fig. 12 is a schematic structural view of the storage bin 31 of the present invention;

fig. 13 is a schematic view of the structure of the roller a and the protrusions of the present invention.

In the figure: a barrel frame 1; a screw shaft 2; a combustion chamber 3; a water tank 4; a fan 5; a transmission shaft A6; a bevel gear A7; a drive shaft B8; a bevel gear B9; a pulley A10; a downcomer 11; a water storage cavity A12; a water storage cavity B13; a pumping cylinder 14; a water pumping rod 15; a water suction tray 16; a check valve 17; a water feed pipe 18; a water pumping frame 19; a connecting rod 20; an eccentric wheel 21; a drive shaft C22; a propeller shaft D23; a bevel gear E24; a feeding port 25; a discharge port 26; a pulley B27; a roller A28; a roller B29; a material containing box 30; a material containing bin 31; an outlet duct 32; a slide door 33; the projections 34; a groove 35; a belt 36.

Detailed Description

Referring to fig. 1 to 7, a process for drying materials without using electric energy can be obtained according to the drawings:

the invention comprises a barrel frame 1, a spiral shaft 2 is rotationally connected in the barrel frame 1, a combustion chamber 3 is fixedly connected on the barrel frame 1, a water tank 4 is fixedly connected on the combustion chamber 3, a fan 5 is rotationally connected in the water tank 4, a transmission shaft A6 is rotationally connected at the left end of the barrel frame 1, the transmission shaft A6 and the fan 5 are in transmission through a first belt, a bevel gear A7 is fixedly connected below the transmission shaft A6, a transmission shaft B8 is rotationally connected on the barrel frame 1, a bevel gear B9 is fixedly connected on the transmission shaft B8, the bevel gear B9 is in meshing transmission with the bevel gear A7, a belt wheel A10 is fixedly connected on the spiral shaft 2, the belt wheel A10 and the transmission shaft B8 are in transmission through a second belt, the whole drying equipment can be transferred without using electric energy, is not required to be installed in a specific place, and can be transferred to a remote mountain area even without electric energy, then the equipment is used for drying materials in remote areas, when the materials are required to be dried, combustible materials can be added into the combustion chamber 3, the combustible materials are combusted in the combustion chamber 3, then water is fully added into the water tank 4, heat is generated after the combustible materials are combusted in the combustion chamber 3, the generated heat is transmitted to the water tank 4, the heat can heat the water in the water tank 4, the water after temperature rise can generate steam, the steam can move upwards, the steam moving upwards can drive the fan 5 to rotate, then the fan 5 rotates and can drive the transmission shaft A6 to rotate through the first belt, then the transmission shaft A6 can drive the bevel gear A7 fixedly connected with the lower end to rotate, the bevel gear A7 rotates and can drive the bevel gear B9 meshed with the bevel gear A7 to rotate, the bevel gear B9 rotates and can drive the transmission shaft B8 fixedly connected with the rear end of the bevel gear to rotate together, the transmission shaft B8 rotates to drive the belt pulley A10 to rotate through the second belt, the spiral shaft 2 is fixedly connected inside the belt pulley A10, the belt pulley A10 drives the spiral shaft 2 to rotate, then the spiral shaft 2 and the barrel frame 1 are heated, when materials enter the barrel frame 1, the materials are dried through the heated spiral shaft 2 and the barrel frame 1, the materials are dried through the spiral shaft 2 rotating in the barrel frame 1 and can be pushed out of the barrel frame 1 again, the dried materials leave the inside of the barrel frame 1 again, and therefore the effect that the materials can be dried without electric energy is achieved.

With reference to fig. 1 to 6, the process of heating the screw shaft 2 and the cartridge holder 1 can be obtained according to what is shown:

according to the invention, the lower end of the water tank 4 is fixedly connected with the sewer pipe 11, the spiral shaft 2 is internally provided with the water storage cavity A12, the barrel frame 1 is internally provided with the water storage cavity B13, the sewer pipe 11 is communicated with the lower end of the water tank 4, after water in the water tank 4 is heated, the water in the water tank 4 can respectively enter the water storage cavity A12 and the water storage cavity B13 through the sewer pipe 11, after hot water enters the water storage cavity B13 arranged in the barrel frame 1, heat is transferred to the barrel frame 1 through the heat transfer and conduction water, so that the temperature of the outer wall of the barrel frame 1 is raised, then after the materials enter the barrel frame 1, the heated barrel frame 1 can dry the materials, meanwhile, the barrel frame 1 dries the materials through the heat transfer of the water, instead of open fire is used for drying the materials, so that the problems of excessive combustion and drying of the materials can not occur, and then hot water flows into the cavity A12 in the spiral shaft 2 through the tail end of the sewer pipe 11, so that the hot water can heat the spiral shaft 2, and the materials can be heated by the spiral shaft 1, and the spiral shaft can be used for heating the materials.

With reference to fig. 1 to 9, a process for the cyclic heating of water in the tank 4 is obtained according to what is shown:

according to the invention, the front end of the barrel frame 1 is fixedly connected with a water pumping barrel 14, the water pumping barrel 14 is connected with a water pumping rod 15 in a sliding manner, the lower end of the water pumping rod 15 is provided with a water pumping disc 16, the water pumping disc 16 is internally provided with a plurality of one-way valves 17, the upper end of the water pumping barrel 14 is fixedly connected with a water feeding pipe 18, the temperature of water is reduced after the water heats the spiral shaft 2 and the barrel frame 1, the water pumping rod 15 moves up and down in the water pumping barrel 14 so as to keep the spiral shaft 2 and the barrel frame 1 heated continuously, the water pumping barrel 14 is fixedly connected with the front end of the barrel frame 1, and then the water pumping rod 15 moves up and down in the water pumping barrel 14, so that the water pumping rod 15 drives the water pumping disc 16 to move up and down in the water pumping barrel 14, the water pumping disc 16 is internally provided with a plurality of one-way valves 17, the one-way valves 17 only enable water to enter from the upper part and not enable water to flow into the lower part from the upper part, when the water pumping disc 16 moves up in the water pumping barrel 14, the pumping disc 16 is tightly matched with the pumping cylinder 14, the pumping disc 16 divides the pumping cylinder 14 into an upper cavity and a lower cavity, the pumping disc 16 moves upwards to generate pressure in the lower cavity, hot water at the tail of the water storage cavity A12 and the water storage cavity B13 is sucked into the lower cavity of the pumping cylinder 14, then the heated hot water in the water tank 4 flows into the water storage cavity A12 and the water storage cavity B13 again through the sewer pipe 11, then when the pumping disc 16 moves downwards in the pumping cylinder 14, the check valves 17 allow water to pass through the check valves 17 after contacting water, so that water in the lower cavity of the pumping cylinder 14 moves upwards to the upper cavity of the pumping cylinder 16 through the check valves 17, so that the water moves to the upper cavity of the pumping cylinder 14, then the pumping disc 16 moves upwards again, the pumping disc 16 and the check valves 17 hold the water to move upwards together, meanwhile, the water pumping disc 16 generates suction force to the lower cavity of the water pumping cylinder 14 again, so that hot water is sucked into the lower cavity of the water pumping cylinder 14 from the water storage cavity A12 and the water storage cavity B13 again, the hot water heated in the water tank 4 flows into the water storage cavity A12 and the water storage cavity B13 again, when the water pumping disc 16 holds the hot water to move upwards, the hot water meets an upper water pipe 18 fixedly connected with the upper end of the water pumping cylinder 14, the water flows into the upper water pipe 18 from the upper cavity of the water pumping cylinder 14, the water flows into the water tank 4 from the upper water pipe 18, the heat cooled from the upper water pipe 18 is heated again by the water tank 4, and the steps are repeated, so that the effect of circularly heating the water in the water tank 4 is obtained.

Referring to fig. 1 to 9, according to the process of the drawing, the water suction rod 15 can be moved up and down circularly:

according to the invention, a pumping frame 19 is fixedly connected to a pumping barrel 14, the pumping rod 15 is slidably connected to the interior of the re-pumping frame 19, a connecting rod 20 is rotatably connected to the left end of the pumping rod 15, an eccentric wheel 21 is rotatably connected to the left end of the pumping barrel 14, the other end of the connecting rod 20 is rotatably connected to the eccentric wheel 21, the eccentric wheel 21 rotates to drive one end of the connecting rod 20 to rotate, the other end of the connecting rod 20 is rotatably connected to the pumping rod 15, the pumping rod 15 is blocked by the pumping frame 19 and cannot rotate, the pumping rod 15 can only slide up and down in the pumping frame 19, when the eccentric wheel 21 drives one end of the connecting rod 20 to rotate to the lowest end, the connecting rod 20 also pulls the pumping rod 15 to slide to the lowest end in the pumping frame 19, when the eccentric wheel 21 drives one end of the connecting rod 20 to rotate to the highest end, the connecting rod 20 also pushes the pumping rod 15 to slide to the highest end in the pumping frame 19, the above steps are repeated, so that the eccentric wheel 21 always rotates, and the pumping rod 15 can drive the pumping rod 15 to slide up and down in the pumping frame 19 through the connecting rod 20 to obtain the circulation effect.

With reference to fig. 1 to 9, a process for keeping the eccentric 21 rotating at all times can be obtained according to what is shown:

according to the invention, a bevel gear E24 is fixedly connected to the left end of the eccentric wheel 21, a transmission shaft D23 is rotatably connected to the left end of the water pumping cylinder 14, a transmission shaft C22 is rotatably connected to the left end of the cylinder frame 1, the rear end of the transmission shaft C22 is in meshing transmission with the bevel gear A7, the front end of the transmission shaft C22 is in meshing transmission with the lower end of the transmission shaft D23, the upper end of the transmission shaft D23 is in meshing transmission with the bevel gear E24, after the fan 5 drives the transmission shaft A6 to rotate through a first belt, the transmission shaft A6 drives the lower bevel gear A7 to rotate, then the bevel gear A7 is in meshing transmission with the rear end first bevel gear of the transmission shaft C22, the bevel gear A7 drives the transmission shaft C22 to rotate through the first bevel gear, another first bevel gear is fixedly connected to the front end of the transmission shaft C22, another first bevel gear is in meshing transmission with a second bevel gear at the lower end of the transmission shaft D23, so that the transmission shaft C22 drives another second bevel gear E23 to rotate, and then the transmission shaft E24 is connected to rotate so that the bevel gear E21 and the transmission shaft E22 is always driven to rotate.

With reference to fig. 1 to 3, a procedure for adding and unloading material can be obtained according to what is shown in the figures:

according to the invention, the lower part of the front end of the barrel frame 1 is provided with the discharge hole 26, the upper part of the rear end of the barrel frame 1 is provided with the feed hole 25, the undried material is added into the feed hole 25 arranged on the upper part of the rear end of the barrel frame 1, then the undried material enters between the barrel frame 1 and the screw shaft 2, then the heated barrel frame 1 and the screw shaft 2 can heat and dry the undried material, the screw shaft 2 rotates along with the material being dried, the screw shaft 2 can drive the screw blade on the outer surface of the screw shaft to rotate, the rotating screw blade can push the material to move towards the front end, the undried material moves ahead while being dried, after the undried material is dried by the barrel frame 1 and the screw shaft 2, the material is also pushed to the front end of the barrel frame 1 by the screw blade, and then the dried material can fall out of the discharge hole 26 arranged on the lower part of the front end of the barrel frame 1, so that the effect of adding and unloading the material is obtained.

Referring to fig. 1 to 10, a convenient material adding process can be obtained according to the drawings:

according to the invention, the roller A28 and the roller B29 are rotatably connected to the barrel frame 1, the rear end of the screw shaft 2 is fixedly connected with the belt wheel B27, the belt wheel B27 and the roller A28 are driven by a third belt, the roller A28 and the roller B29 are driven by a belt 36, the belt 36 is provided with a plurality of material containing boxes 30, the belt wheel B27 fixedly connected with the belt wheel B27 is driven to rotate after the screw shaft 2 rotates, the roller A28 is driven to rotate by the third belt after the belt wheel B27 rotates, the roller A28 drives the roller B29 to rotate by the belt 36, so that the whole belt 36 rotates between the roller A28 and the roller B29, then the belt 36 is provided with a plurality of material containing boxes 30, the plurality of material containing boxes 30 move along with the belt 36, when the materials are placed on the belt 36, the plurality of material containing boxes 30 on the belt 36 receive the materials, the belt 36 rotates anticlockwise after the plurality of material containing boxes 30 receive the materials, the plurality of material containing boxes 30 rise along with the belt 36, when the materials are placed on the belt 36, the top end of the roller A30 is lifted, the material containing boxes, the material receiving process is reduced, and the labor intensity of workers is reduced.

With reference to fig. 1 to 12, a further convenient process for adding material can be obtained according to the figures:

according to the invention, the right end of the barrel frame 1 is fixedly connected with the material containing bin 31, the material containing bin 31 is added below the roller B29, the material containing bin 31 has a width larger than that of the belt 36, the inner part of the material containing bin 31 is an inward inclined plane, the left end of the material containing bin 31 is provided with a width allowing the material containing bin 30 to pass through, a worker can directly add materials into the material containing bin 31, the materials entering the material containing bin 31 can be contained by the material containing bin 30 passing through the material containing bin 31, and then the worker does not need to stably place the materials on the belt 36 along with the rising of the belt 36, so that the operation requirement on the worker is reduced, and the effect of further and conveniently adding the materials is obtained.

With reference to fig. 1 to 6, a process for adding water to the water tank 4 can be obtained according to what is shown in the figures:

according to the invention, the air outlet pipe 32 is fixedly connected to the water tank 4, the sliding door 33 is connected to the combustion chamber 3 in a sliding manner, along with the combustion of combustible substances in the combustion chamber 3, the water in the water tank 4 can be evaporated and reduced, and redundant water vapor can burst out of the air outlet pipe 32 fixedly connected to the water tank 4, so that explosion caused by excessive pressure in the water tank 4 can be avoided, after the evaporation of the water in the water tank 4 is reduced, new water can be filled into the water tank 4 through the air outlet pipe 32, so that the water storage cavity A12 and the water storage cavity B13 can always keep hot water, after enough combustible substances are added into the combustion chamber 3, the sliding door 33 can slide towards the rear end in the combustion chamber 3, so that the sliding door 33 blocks part of rectangular holes formed in the combustion chamber 3, the combustible substances in the combustion chamber 3 are prevented from splashing out to cause fire, and the effect of adding water into the water tank 4 is obtained.

Referring to fig. 1 to 13, a process for preventing the belt 36 from slipping can be obtained according to the illustration:

according to the invention, a plurality of grooves 35 are formed in the belt 36, a plurality of protrusions 34 are formed on the peripheries of the roller A28 and the roller B29, and the protrusions 34 can be inserted into the grooves 35 in the belt 36, so that the relative contact area of the belt 36 with the roller A28 and the roller B29 is increased, the relative friction force between the belt 36 and the roller A28 and the roller B29 is increased, when the belt 36 slips, the protrusions 34 are inserted into the grooves 35 in the belt 36, and the protrusions 34 can prevent the belt 36 from being displaced relative to the roller A28 and the roller B29. Only when the roller a28 and the roller B29 rotate simultaneously, the belt 36 can rotate around the roller a28 and the roller B29, thereby obtaining an effect of preventing the belt 36 from slipping.

Claims

1. An energy-saving drying equipment which characterized in that: including barrel holder (1) and screw axis (2) of rotation connection in barrel holder (1), fixedly connected with combustion chamber (3) is gone up in barrel holder (1), fixedly connected with water tank (4) is gone up in combustion chamber (3), water tank (4) internal rotation is connected with fan (5), the left end rotation of barrel holder (1) is connected with transmission shaft A (6), transmission shaft A (6) with fan (5) are through first belt drive, transmission shaft A (6) below fixedly connected with bevel gear A (7), it is connected with transmission shaft B (8) to rotate on barrel holder (1), fixedly connected with bevel gear B (9) are gone up in transmission shaft B (8), bevel gear B (9) with bevel gear A (7) meshing transmission, fixedly connected with band pulley A (10) are gone up in screw axis (2), band pulley A (10) with transmission shaft B (8) are through second belt drive.

2. An energy saving drying apparatus according to claim 1, wherein: the lower end of the water tank (4) is fixedly connected with a sewer pipe (11), a water storage cavity A (12) is arranged in the spiral shaft (2), and a water storage cavity B (13) is arranged in the barrel frame (1).

3. An energy saving drying apparatus according to claim 2, wherein: the front end fixedly connected with of barrel holder (1) draws water a section of thick bamboo (14), sliding connection has a pole (15) of drawing water in a section of thick bamboo (14), the lower extreme of pole (15) of drawing water is provided with water pumping disc (16), be provided with a plurality of check valves (17) in water pumping disc (16), the upper end fixedly connected with water pipe (18) of a section of thick bamboo (14) of drawing water.

4. An energy saving drying apparatus according to claim 3, wherein: draw water on a section of thick bamboo (14) fixedly connected with frame (19), water pumping rod (15) sliding connection is in frame (19) draws water, water pumping rod (15) left end rotates the one end that is connected with connecting rod (20), the left end rotation of a section of thick bamboo (14) that draws water is connected with eccentric wheel (21), the other end rotation of connecting rod (20) is connected on eccentric wheel (21).

5. An energy saving drying apparatus according to claim 4, wherein: the left end fixedly connected with bevel gear E (24) of eccentric wheel (21), it is connected with transmission shaft D (23) to draw water a section of thick bamboo (14) left end rotation, the barrel holder (1) left end rotation is connected with transmission shaft C (22), the rear end of transmission shaft C (22) with bevel gear A (7) meshing, the front end of transmission shaft C (22) with the lower extreme meshing of transmission shaft D (23), the upper end of transmission shaft D (23) with bevel gear E (24) meshing.

6. An energy saving drying apparatus according to claim 1, wherein: the lower part of the front end of the barrel frame (1) is provided with a discharge hole (26), and the upper part of the rear end of the barrel frame (1) is provided with a feeding hole (25).

7. An energy saving drying apparatus according to claim 6, wherein: the drum rack is characterized in that a roller A (28) and a roller B (29) are rotatably connected to the drum rack (1), a belt wheel B (27) is fixedly connected to the rear end of the spiral shaft (2), the belt wheel B (27) and the roller A (28) are in transmission through a third belt, the roller A (28) and the roller B (29) are in transmission through a belt (36), and a plurality of material containing boxes (30) are arranged on the belt (36).

8. An energy saving drying apparatus according to claim 7, wherein: the right end of the barrel frame (1) is fixedly connected with a material containing bin (31).

9. An energy saving drying apparatus according to claim 5, wherein: an air outlet pipe (32) is fixedly connected to the water tank (4), and a sliding door (33) is connected to the combustion chamber (3) in a sliding mode.

10. An energy saving drying apparatus according to claim 8, wherein: the inside of belt (36) is provided with a plurality of recesses (35), and the periphery of gyro wheel A (28) and gyro wheel B (29) is provided with a plurality of archs (34).