JP2021159905A - Fine-crushing device capable of ensuring uniformity of crushed coal grain size - Google Patents

Abstract

To disclose a fine-crushing device capable of ensuring uniformity of a crushed coal grain size.SOLUTION: A crushing box is comprised. A crushing space opened downward is installed in the crushing box. A crushing device for pressing the coal downward and crushing the coal is installed in the crushing space. The crushing device comprises a transmission space positioned in a rear side of the crushing space. A transmission shaft becoming symmetric is rotatably connected in a front side inner wall of the transmission space. Gears are installed together so as to be engaged to each other in the transmission shaft. A crushing rotor positioned in the crushing space is installed in the transmission shaft. A pushing plate positioned in an upper side of the crushing rotor is slidably connected in the crushing space. The pushing plate moves downward and provides a downward pressure, and thereby makes the coal adhere to an upper edge of the crushing rotor. Also, the crushing rotor is made turn to each other by the gear to transmission, and thereby the polishing of the coal is ensured. A transportation space is installed symmetrically positionally in both right and left sides of the crushing space.SELECTED DRAWING: Figure 1

Description

The present invention relates to the technical field of coal crushing, and specifically to a fine crushing apparatus capable of guaranteeing the uniformity of crushed coal particle size.

After being excavated from the ground, coal differs in form and size and affects subsequent processing. In conventional coal crushing, the crushing operation is generally performed by a pair of rotors or pendulums.
However, while the conventional pendulum has a single structure, the shape of the coal is different and the particle size of the crushed coal is also different. In addition, in the case of rotor-type pressing, there is a possibility of slipping against circular coal, the amount of coal charged each time is different, and the gravity of the coal on the upper side of the rotor pressing downward is also different, so the crushing particle size is non-uniform. Is. The fine crushing apparatus capable of guaranteeing the uniformity of the crushed coal particle size of the present invention can solve the above problems.

Chinese Patent Application Publication No. 105032585

Neither the pendulum crushing means nor the rotor crushing means can guarantee the uniformity of the particle size for crushing coal.

A crushing device that can guarantee the uniformity of the grain size of crushed coal, including a crushing box, a crushing space opened downward is installed in the crushing box, and coal is pressed downward in the crushing space. A crushing device is installed, and the crushing device includes a transmission space located behind the crushing space, and a symmetrical transmission axis is rotatably connected to the front inner wall of the transmission space. , The transmission shaft is installed so that the gears mesh with each other, the transmission shaft is installed with a crushing rotor located in the crushing space, and the crushing rotor is located above the crushing rotor in the crushing space. The pressing plates are slidably connected, and the pressing plates move downward to provide downward pressure to bring the coal into close contact with the upper end of the crushing rotor, and gear vs. transmission to bring the crushing rotors to each other. By rotating the coal, the polishing of the coal is guaranteed, the transport spaces are installed symmetrically on the left and right sides of the crushing space, and the connecting holes communicate with each other between the transport space and the crushing space. In the transport space, a transport device that pushes coal in a fixed amount each time is installed, and the transport device includes a placing plate located in the transport space and is on the lower inner wall of the transport space. The pad blocks are slidably connected, a parallel moving plate is fixedly installed on the upper side of the pad block, and a transport passage slidably connected to the rotary groove is installed on the parallel moving plate. An elevating space is installed on the upper side of the passage, and a stop plate capable of closing the upper side of the transport passage and the placing plate is slidably connected to the lower side of the elevating space, and the stop plate slides vertically to the above. By altering the opening and closing of the transport passages, it is ensured that the translation plates do not push outward when they separate from each other, and that the translation plates enter the crushing space when they are close to each other. A drive device for driving the slide of the translation plate is installed between the transportation space and the crushing space, and the pressing plate is raised and lowered and the crushing rotor is installed in the transmission space. A synchronization device is installed that is generated in synchronization with the rotation of.

Advantageously, a support frame is fixedly installed under the transportation space.

The crushing device also includes a sieve connected to the inner wall of the crushing space by a braid and located below the crushing rotor.

The transport device includes a guide roller rotatably connected to the inner wall of the elevating space, a hinge spring is connected between the stop plate and the lower inner wall of the elevating space, and the crushing is performed in the transport space. A fixing ring is fixedly connected to the inner wall on the side away from the space, and a tow hinge slidably connected to the guide roller is fixedly connected between the fixing ring and the stop plate. A rotary groove is formed in the placing plate, a rotating plate is rotatably connected to the rotating groove, a hinge connecting rod is connected to the lower end of the rotating plate by a hinge, and a hinge connecting rod is connected to the lower end of the hinge connecting rod. A rolling ring slidably connected to the upper end surface of the pad block is rotatably connected, and is installed so as to penetrate the placing space on the inner wall on the side away from the crushing space in the transport space. Is provided with an inclined plate that is fixedly connected to the rotary groove.

The drive device includes a driven shaft that is rotatably connected to the inner wall of the transport space and extends to the inside of the crushed space, and the driven shaft is provided with a rotary cylinder located inside the transport space. A raceway groove slidably connected to the upper side of the parallel moving plate is formed in the rotary cylinder, and an auxiliary bevel gear located in the crushing space is installed in the driven shaft.

The synchronization device includes a drive shaft rotatably connected to the front inner wall of the transmission space, the drive shaft is provided with a main gear that meshes with the sub gear, and the drive shaft is equipped with the crushing space. A rotating disk located inside the rotating disk is installed, a fixing pin is installed on the front end surface of the rotating disk, and a connecting frame slidably connected to the fixing pin is fixedly installed on the upper side of the pressing plate. A main pulley located inside the transmission space is installed on the drive shaft, and a motor fitted in the rear inner wall of the transmission space is movably connected to the rear side of the drive shaft so that the transmission on the left side can be transmitted. A sub-pulley located inside the transmission space is installed on the shaft, and a belt is connected between the sub-pulley and the main pulley.

Beneficial effect: In the present invention, the left and right sides slide inward or outward at the same time, the parts that slide inward are combined, the transportation passage is opened, and the parts that slide outward are closed, so that the coal is on one side. Coal and the upper side of the crushing rotor are brought into close contact with each other according to a pressing mechanism that can be transported only to the coal and moves up and down in synchronization with the coal transportation structure, the process of pressing and crushing is guaranteed, and coal with an appropriate particle size is sorted by a sieve. , Guarantee the uniformity of particle size for crushing coal.

In order to explain the present invention in detail and conveniently explain the present invention together with FIGS. 1 to 3 below, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention and is described in the present application. Each direction is the direction when the device is viewed in the same direction as in FIG.

Overall configuration diagram of the crushing device that can guarantee the uniformity of the crushed coal particle size Configuration diagram in the AA direction in FIG. Configuration diagram in the BB direction in FIG.

A fine crushing device that can guarantee the uniformity of the grain size of crushed coal, including a crushing box 11, a crushing space 12 opened downward is installed in the crushing box 11, and coal is contained in the crushing space 12. A crushing device 901 is installed to crush by pressing the crushing device 901 downward, and the crushing device 901 includes a transmission space 46 located behind the crushing space 12, and is symmetrical to the front inner wall of the transmission space 46. The transmission shafts 33 are rotatably connected, gears 49 are installed on the transmission shafts 33 so as to mesh with each other, and a crushing rotor 34 located in the crushing space 12 is installed on the transmission shafts 33. A pressing plate 17 located above the crushing rotor 34 is slidably connected to the crushing space 12, and the pressing plate 17 moves downward to provide downward pressure, thereby causing the coal to flow. The crushing rotor 34 is brought into close contact with the upper end of the crushing rotor 34, and the crushing rotor 34 is rotated with respect to each other by gear translation to guarantee the polishing of coal. It is installed symmetrically, a connecting hole 38 is installed between the transport space 18 and the crushing space 12 so as to communicate with each other, and a transport device 902 that pushes coal in a fixed amount each time is installed in the transport space 18. The transport device 902 includes a placing plate 50 located in the transport space 18, and the pad block 31 is slidably connected to the lower inner wall of the transport space 18 so as to be above the pad block 31. The translation plate 24 is fixedly installed, a transportation passage 37 slidably connected to the rotation groove 28 is installed in the translation plate 24, and an elevating space 39 is installed above the transportation passage 37. A stop plate 40 capable of closing the upper side of the transport passage 37 and the placement plate 50 is slidably connected to the lower side of the elevating space 39, and the stop plate 40 slides vertically to open and close the transport passage 37. By changing the above, it is guaranteed that the translation plates 24 do not push the coal outward when they are separated from each other, and the coal is pushed into the crushing space 12 when the translation plates 24 are close to each other. A drive device 903 for driving the slide of the translation plate 24 is installed between the transportation space 18 and the crushing space 12, and the pressing plate 17 is installed in the transmission space 46. A synchronization device 904 that synchronizes the raising and lowering and the rotation of the crushing rotor 34 is installed.

Advantageously, a support frame 32 is fixedly installed below the transport space 18, which allows the storage box to move below the crushing space 12.

The crusher 901 also includes a sieve 35 that is connected to the inner wall of the crushing space 12 by a braid and is located below the crushing rotor 34, the sieve 35 capable of sorting coal of acceptable particle size.

The transport device 902 includes a guide roller 41 rotatably connected to the inner wall of the elevating space 39, and a hinge spring 25 is connected between the stop plate 40 and the lower inner wall of the elevating space 39. A fixing ring 22 is fixedly connected to the inner wall of the transport space 18 on the side away from the crushing space 12, and is slidably connected to the guide roller 41 between the fixing ring 22 and the stop plate 40. The towed hinges 23 are fixedly connected, a rotary groove 28 is formed in the placing plate 50, a rotating plate 27 is rotatably connected to the rotating groove 28, and the rotating plate 27 is rotatably connected to the lower end of the rotating plate 27. The hinge connecting rod 29 is connected by a hinge, and a rolling ring 30 slidably connected to the upper end surface of the pad block 31 is rotatably connected to the lower end of the hinge connecting rod 29. A placing space 26 is installed on the inner wall on the side away from the crushing space 12 so as to penetrate the placing space 26, and an inclined plate 36 fixedly connected to the rotating groove 28 is installed in the placing plate 50, and the parallel moving plate is installed. In the moving process of 24, the retaining plate 40 moves downward due to the loosening of the tow rope 23 due to the elasticity of the blocking spring 25, thereby blocking the transport passage 37.

The drive device 903 includes a driven shaft 20 that is rotatably connected to the inner wall of the transport space 18 and extends to the inside of the crushing space 12, and the driven shaft 20 is located inside the transport space 18. A rotary cylinder 19 is installed, a raceway groove 21 slidably connected to the upper side of the parallel moving plate 24 is formed in the rotary cylinder 19, and a secondary shaft 20 is located in the crushing space 12 on the driven shaft 20. A bevel gear 43 is installed, the driven shaft 20 rotates the rotary cylinder 19, and the inner wall of the raceway groove 21 limits the translation plate 24, thereby moving the translation plate 24 left and right.

The synchronization device 904 includes a drive shaft 15 rotatably connected to the front inner wall of the transmission space 46, and the drive shaft 15 is provided with a main gear 44 that meshes with the sub gear 43 to drive the drive shaft 15. A rotating disk 14 located inside the crushing space 12 is installed on the shaft 15, a fixing pin 16 is installed on the front end surface of the rotating disk 14, and the fixing pin 16 and a slide are installed on the upper side of the pressing plate 17. A connecting frame 13 that is possibly connected is fixedly installed, a main pulley 42 located inside the transmission space 46 is installed on the drive shaft 15, and the transmission space 46 is behind the drive shaft 15. A motor 45 fitted in the inner wall on the rear side of the vehicle is movably connected, and a sub-pulley 48 located inside the transmission space 46 is installed on the transmission shaft 33 on the left side, and the sub-pulley 48 and the main pulley 42 are installed. A belt 47 is connected to and the motor 45 is activated to rotate the drive shaft 15, rotate the turntable 14, and the fixing pin 16 slides inside the connecting frame 13. The pressing plate 17 is pushed up and down, and the drive shaft 15 rotates the transmission shaft 33 on the left side by belt transmission, and the crushing rotors 34 on both the left and right sides are rotated with respect to each other by a gear pair.

The usage of the present invention will be described with reference to FIGS.
In the initial state, the pressing plate 17 is separated from the crushing rotor 34, the parallel moving plate 24 is approaching the space 26, and the rotating plate 27 is placed horizontally.
At the time of operation, the coal to be processed manually is placed on the upper side of the placing plate 50 and the rotating plate 27, the motor 45 is started to rotate the drive shaft 15, and the drive shaft 15 is the auxiliary bevel gear 43 and the main bevel gear 44. The driven shaft 20 is rotated by meshing transmission, and when the driven shaft 20 makes a half turn, the rotary cylinder 19 rotates and the parallel moving plate 24 is restricted by the inner wall of the raceway groove 21 so that the parallel moving plates 24 approach each other. At this time, the distance between the guide roller 41 and the fixing ring 22 increases, and due to the limitation of the tow rope 23 and the rotation of the guide roller 41, the stop plate 40 is pulled upward to store elastic energy in the blocking spring 25. At this time, the transport passage 37 is gradually opened, and the coal on the side away from the crushing space 12 is pushed by the rotating plate 27, and at the same time, the contact portion between the rolling wheel 30 and the pad block 31 increases, so that the hinge connecting rod 29 Pushes the rotating plate 27 upward and turns it, and at the same time as the coal passes through the inclined plate 36 and falls from the connecting hole 38 into the inside of the crushing space 12, the driving shaft 15 rotates at once with the main pulley 42. The left transmission shaft 33 is rotated through the belt 47 and the auxiliary pulley 48, the left transmission shaft 33 rotates the crushing rotors 34 on both the left and right sides with respect to each other by gear pair transmission, and the drive shaft 15 is the rotating disk 14 The fixing pin 16 slides on the inner wall of the connecting frame 13 to push the pressing plate 17 downward, thereby pressing the coal downward, bringing the coal into close contact with the upper surface of the crushing rotor 34, and the coal. Press crushing, and the coal falls on the sieve 35, and the coal with a passing grain size falls off the sieve 35, which guarantees the uniformity of the grain size of the coal.
The driven shaft 20 continues to rotate half a circumference, each part is repositioned, and the next operation is performed.

According to the above method, those skilled in the art can carry out various changes according to the operation pattern within the scope of the present invention.

Claims (6)

A crushing device that can guarantee the uniformity of the grain size of crushed coal, including a crushing box, a crushing space opened downward is installed in the crushing box, and coal is pressed downward in the crushing space. A crushing device is installed, and the crushing device includes a transmission space located behind the crushing space, and a symmetrical transmission axis is rotatably connected to the front inner wall of the transmission space. , The transmission shaft is installed so that the gears mesh with each other, the transmission shaft is installed with a crushing rotor located in the crushing space, and the crushing rotor is located above the crushing rotor in the crushing space. The pressing plates are slidably connected, and the pressing plates move downward to provide downward pressure to bring the coal into close contact with the upper end of the crushing rotor, and gear vs. transmission to bring the crushing rotors to each other. By rotating the coal, the polishing of the coal is guaranteed, the transport spaces are installed symmetrically on the left and right sides of the crushing space, and the connecting holes communicate with each other between the transport space and the crushing space. In the transport space, a transport device that pushes coal in a fixed amount each time is installed, and the transport device includes a placing plate located in the transport space and is on the lower inner wall of the transport space. The pad blocks are slidably connected, a parallel moving plate is fixedly installed on the upper side of the pad block, and a transport passage slidably connected to the rotary groove is installed on the parallel moving plate. An elevating space is installed on the upper side of the passage, and a stop plate capable of closing the upper side of the transport passage and the placing plate is slidably connected to the lower side of the elevating space, and the stop plate slides vertically to the above. By altering the opening and closing of the transport passages, it is ensured that the translation plates do not push outward when they separate from each other, and that the translation plates enter the crushing space when they are close to each other. A drive device for driving the slide of the translation plate is installed between the transportation space and the crushing space, and the pressing plate is raised and lowered and the crushing rotor is installed in the transmission space. A fine crushing device that can guarantee the uniformity of the crushed coal particle size, which is characterized in that a synchronous device that is generated in synchronization with the rotation of the crushed coal is installed. The fine crushing apparatus according to claim 1, wherein a support frame is fixedly installed on the lower side of the transport space, and the uniformity of the crushed coal particle size can be guaranteed. The crushing apparatus according to claim 1, wherein the crushing apparatus also includes a sieve connected to the inner wall of the crushing space by an assembly and located below the crushing rotor, and can guarantee the uniformity of the crushed coal particle size. Shattering device. The transport device includes a guide roller rotatably connected to the inner wall of the elevating space, a hinge spring is connected between the stop plate and the lower inner wall of the elevating space, and the crushing is performed in the transport space. A fixing ring is fixedly connected to the inner wall on the side away from the space, and a tow hinge slidably connected to the guide roller is fixedly connected between the fixing ring and the stop plate. A rotary groove is formed in the placing plate, a rotating plate is rotatably connected to the rotating groove, a hinge connecting rod is connected to the lower end of the rotating plate by a hinge, and a hinge connecting rod is connected to the lower end of the hinge connecting rod. A rolling ring slidably connected to the upper end surface of the pad block is rotatably connected, and is installed so as to penetrate the placing space on the inner wall on the side away from the crushing space in the transport space. The fine crushing apparatus according to claim 1, wherein an inclined plate fixedly connected to the rotary groove is installed in the crushing coal, which can guarantee the uniformity of the grain size of the crushed coal. The drive device includes a driven shaft that is rotatably connected to the inner wall of the transport space and extends to the inside of the crushed space, and the driven shaft is provided with a rotary cylinder located inside the transport space. The rotating cylinder is formed with a raceway groove slidably connected to the upper side of the parallel moving plate, and the driven shaft is provided with an auxiliary bevel gear located in the crushing space. The fine crushing apparatus according to claim 1, which can guarantee the uniformity of the crushed coal particle size. The synchronization device includes a drive shaft rotatably connected to the front inner wall of the transmission space, the drive shaft is provided with a main gear that meshes with the sub gear, and the drive shaft is equipped with the crushing space. A rotating disk located inside the rotating disk is installed, a fixing pin is installed on the front end surface of the rotating disk, and a connecting frame slidably connected to the fixing pin is fixedly installed on the upper side of the pressing plate. A main pulley located inside the transmission space is installed on the drive shaft, and a motor fitted in the rear inner wall of the transmission space is movably connected to the rear side of the drive shaft so that the transmission on the left side can be transmitted. The crushed coal particle size according to claim 5, wherein a sub-pulley located inside the transmission space is installed on the shaft, and a belt is connected between the sub-pulley and the main pulley. A crusher that can guarantee uniformity.

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