CN114178021A - Ceramic clay crushing and iron removing mechanism and using method thereof - Google Patents
Ceramic clay crushing and iron removing mechanism and using method thereof Download PDFInfo
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- CN114178021A CN114178021A CN202111501716.6A CN202111501716A CN114178021A CN 114178021 A CN114178021 A CN 114178021A CN 202111501716 A CN202111501716 A CN 202111501716A CN 114178021 A CN114178021 A CN 114178021A
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- iron
- hammering
- spherical shell
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- sliding
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- XEEYBQQBJWHFJM-UHFFFAOYSA-N Iron Chemical compound [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 title claims abstract description 469
- 229910052742 iron Inorganic materials 0.000 title claims abstract description 234
- 239000004927 clay Substances 0.000 title claims abstract description 51
- 230000007246 mechanism Effects 0.000 title claims abstract description 46
- 239000000919 ceramic Substances 0.000 title claims abstract description 38
- 238000000034 method Methods 0.000 title claims abstract description 28
- 230000005540 biological transmission Effects 0.000 claims abstract description 12
- 239000007787 solid Substances 0.000 claims abstract description 7
- 238000004140 cleaning Methods 0.000 claims description 103
- 239000006185 dispersion Substances 0.000 claims description 77
- 239000010720 hydraulic oil Substances 0.000 claims description 46
- 238000007599 discharging Methods 0.000 claims description 43
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 28
- 239000007788 liquid Substances 0.000 claims description 18
- 238000003860 storage Methods 0.000 claims description 18
- 238000005303 weighing Methods 0.000 claims description 17
- 230000008859 change Effects 0.000 claims description 3
- 238000010298 pulverizing process Methods 0.000 claims 15
- 239000012535 impurity Substances 0.000 description 10
- 230000009471 action Effects 0.000 description 9
- 239000002245 particle Substances 0.000 description 9
- 230000008569 process Effects 0.000 description 8
- 239000000463 material Substances 0.000 description 7
- 239000002994 raw material Substances 0.000 description 6
- 238000007789 sealing Methods 0.000 description 6
- 230000005484 gravity Effects 0.000 description 3
- VYPSYNLAJGMNEJ-UHFFFAOYSA-N Silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 description 2
- 230000006872 improvement Effects 0.000 description 2
- 238000011065 in-situ storage Methods 0.000 description 2
- 239000011324 bead Substances 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000001627 detrimental effect Effects 0.000 description 1
- 238000001125 extrusion Methods 0.000 description 1
- 238000010304 firing Methods 0.000 description 1
- 238000002347 injection Methods 0.000 description 1
- 239000007924 injection Substances 0.000 description 1
- NLYAJNPCOHFWQQ-UHFFFAOYSA-N kaolin Chemical compound O.O.O=[Al]O[Si](=O)O[Si](=O)O[Al]=O NLYAJNPCOHFWQQ-UHFFFAOYSA-N 0.000 description 1
- 238000004519 manufacturing process Methods 0.000 description 1
- 239000000203 mixture Substances 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- TWNQGVIAIRXVLR-UHFFFAOYSA-N oxo(oxoalumanyloxy)alumane Chemical compound O=[Al]O[Al]=O TWNQGVIAIRXVLR-UHFFFAOYSA-N 0.000 description 1
- 230000000737 periodic effect Effects 0.000 description 1
- 230000000704 physical effect Effects 0.000 description 1
- 239000004576 sand Substances 0.000 description 1
- 238000012216 screening Methods 0.000 description 1
- 238000000926 separation method Methods 0.000 description 1
- 229910052604 silicate mineral Inorganic materials 0.000 description 1
- 229910052814 silicon oxide Inorganic materials 0.000 description 1
- 239000002689 soil Substances 0.000 description 1
- 239000004575 stone Substances 0.000 description 1
- 239000000126 substance Substances 0.000 description 1
Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C19/00—Other disintegrating devices or methods
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C21/00—Disintegrating plant with or without drying of the material
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C23/00—Auxiliary methods or auxiliary devices or accessories specially adapted for crushing or disintegrating not provided for in preceding groups or not specially adapted to apparatus covered by a single preceding group
- B02C23/08—Separating or sorting of material, associated with crushing or disintegrating
- B02C23/10—Separating or sorting of material, associated with crushing or disintegrating with separator arranged in discharge path of crushing or disintegrating zone
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C—MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03C1/00—Magnetic separation
- B03C1/02—Magnetic separation acting directly on the substance being separated
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P40/00—Technologies relating to the processing of minerals
- Y02P40/60—Production of ceramic materials or ceramic elements, e.g. substitution of clay or shale by alternative raw materials, e.g. ashes
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- Engineering & Computer Science (AREA)
- Food Science & Technology (AREA)
- Crushing And Grinding (AREA)
Abstract
The invention belongs to the field of pretreatment of ceramic clay, and particularly relates to a ceramic clay crushing and iron removing mechanism and a using method thereof. The utility model provides a deironing mechanism is smashed to pottery clay includes end frame, end frame has set firmly the motor, the symmetry has set firmly perpendicular frame in the end frame, the output of motor has set firmly main pivot, be equipped with the outer lane spherical shell in the main pivot, a plurality of outer lane spherical shell through-holes have been seted up on the outer lane spherical shell, the long spout of a plurality of outer lane spherical shell arcs has been seted up on the outer lane spherical shell, be equipped with reciprocating sliding's circle spherical shell arc in the long spout of every outer lane spherical shell arc and move the slider, be equipped with annular power transmission mechanism on the outer lane spherical shell, but set firmly free rotation's hammering moving axis on the annular power transmission mechanism, the cover is equipped with the solid axle of hammering on the moving axis, the solid epaxial inner circle spherical shell that has set firmly of hammering, a plurality of inner circle spherical shell through-holes have evenly been seted up on the ball shell of hammering, the fixed pole of hammering has set firmly the hammering, the hammering spout has been seted up on the fixed pole, but reciprocating sliding's hammering pole is equipped with reciprocating sliding hammering in the hammering spout.
Description
Technical Field
The invention belongs to the field of pretreatment of ceramic clay, and particularly relates to a ceramic clay crushing and iron removing mechanism and a using method thereof.
Background
The clay is the soil with little sand and viscosity, and has better plasticity because the moisture is not easy to pass through the clay. Typical clays are formed from silicate minerals after weathering on the earth's surface. Generally, in situ weathering is carried out with larger particles and a composition close to the original stone, which is called primary clay or primary clay. The clay mainly comprises silicon oxide and aluminum oxide, is white and fireproof, and is a main raw material for preparing porcelain clay. The prior pretreatment process of ceramic clay has the following problems:
1. in the pretreatment process, the raw material of the clay has certain strength, and the initial raw material particles of the clay are large, so that the clay is not beneficial to subsequent crushing, grinding and iron treatment.
2. Due to process limitations, the iron content of clay used for ceramic firing needs to be controlled to ensure the product quality.
3. Clay particles need to be ground controllably to control particle density.
4. Clay does not exclude other substances, which, although having certain physical properties, are still detrimental to the subsequent ceramic production.
In conclusion, the ceramic clay crushing and deironing mechanism which is efficient in crushing, capable of controllably crushing particles, has the deironing function and can also screen out other impurities and the use method thereof are designed.
Disclosure of Invention
The invention aims to provide a ceramic clay crushing and iron removing mechanism and a using method thereof, aiming at the problems in the prior art.
In order to achieve the purpose, the invention adopts the following technical scheme: a ceramic clay crushing and iron removing mechanism and a using method thereof are carried out by matching with a ceramic clay crushing and iron removing mechanism, the ceramic clay crushing and iron removing mechanism comprises a bottom frame, a motor mounting groove is arranged on the bottom frame, vertical frames are symmetrically and fixedly arranged on the bottom frame, a motor is fixedly arranged in the motor mounting groove, a main rotating shaft is fixedly arranged at the output end of the motor, an outer ring spherical shell is fixedly arranged on the main rotating shaft, a plurality of outer ring spherical shell through holes are uniformly arranged on the outer ring spherical shell, a plurality of outer ring spherical shell arc long chutes are uniformly arranged on the outer ring spherical shell, a ring spherical shell arc movable sliding block capable of sliding back and forth is arranged in each outer ring spherical shell arc long chute, an annular power transmission mechanism is fixedly arranged on the outer ring spherical shell, a hammering movable shaft capable of rotating freely is fixedly arranged on the annular power transmission mechanism, and a hammering fixed shaft capable of rotating freely relatively is sleeved on the hammering movable shaft, the hammering fixed shaft is fixedly provided with an inner ring spherical shell, a plurality of inner ring spherical shell through holes are uniformly formed in the inner ring spherical shell, a hammering fixed rod is fixedly arranged on the hammering movable shaft, a hammering sliding groove is formed in the hammering fixed rod, a hammering moving rod capable of sliding in a reciprocating mode is arranged in the hammering sliding groove, a hammering spring is fixedly arranged between the hammering moving rod and the hammering sliding groove, and an upper hammering ball layer is fixedly arranged on the hammering moving rod.
Preferably, a hammering ball rotating shaft capable of freely rotating is arranged on the upper hammering ball layer, a middle hammering ball layer is fixedly arranged on the hammering ball rotating shaft, four cleaning dispersion sliding chutes are uniformly formed in the middle hammering ball layer, a lower hammering ball layer capable of freely rotating is arranged on the hammering ball rotating shaft, four cleaning dispersion hydraulic sliding chutes are uniformly formed in the middle hammering ball layer, a cleaning dispersion hydraulic sliding block capable of freely sliding is arranged in each cleaning dispersion hydraulic sliding chute, a cleaning dispersion hydraulic sliding rod extending out of each cleaning dispersion hydraulic sliding chute is fixedly arranged on each cleaning dispersion hydraulic sliding block, a cleaning dispersion hydraulic spring is fixedly arranged between each cleaning dispersion hydraulic sliding block and each cleaning dispersion hydraulic sliding chute, a cleaning dispersion sliding block capable of reciprocally sliding in each cleaning dispersion sliding chute is fixedly arranged on each cleaning dispersion hydraulic sliding rod, and a cleaning dispersion arc-shaped sliding plate is fixedly arranged on each cleaning dispersion sliding block, the inner wall of inner circle spherical shell set firmly can with well hammering ball layer and the broken parting bead of lower hammering ball layer cooperation, the hammering moves the pole go up hammering ball layer hammering ball pivot well hammering ball in situ set firmly the intercommunication clean dispersion hydraulic pressure spout with the hammering hydraulic pressure of hammering spout is said.
Preferably, annular power transmission mechanism includes the outer lane spherical shell, the frame that changes has set firmly on the outer lane spherical shell, the helical gear ring has set firmly in the frame that changes, the helical gear ring has been seted up on the helical gear ring, helical gear ring inslot symmetry is equipped with the driven helical gear of meshable, the hammering moving axis has set firmly altogether between the helical gear, the hammering is fixed epaxially has seted up can help go up hammering ball layer, well hammering ball layer and the broken hammering solid axial trough of lower hammering ball layer.
Preferably, set firmly the butt on the outer lane spherical shell in the center arc piece of inner circle spherical shell, set up on the center arc piece with circle spherical shell arc moves the crashproof spout that slider quantity is unanimous, every but reciprocating sliding's crashproof slide bar in the crashproof spout, every crashproof slide bar with anticollision spring has set firmly between the crashproof spout, every set firmly on the crashproof slide bar can seal crashproof spout and can with the crashproof head of slider butt is moved to circle spherical shell arc, every set firmly the crashproof head that can absorb iron fillings on the slider is moved to circle spherical shell arc, every set up a plurality of clean through-hole spouts on the slider is moved to circle spherical shell arc, every but be equipped with reciprocating sliding and can clear up in the clean through-hole spout the clean through-hole slider of inner circle spherical shell through-hole, every clean through-hole slider with clean through-hole spring has set firmly between the clean through-hole spout.
Preferably, the outer ring spherical shell is uniformly provided with outer ring spherical shell sliding grooves with the same number as the outer ring spherical shell arc long sliding grooves, each outer ring spherical shell sliding groove is internally provided with an outer ring spherical shell arc sliding block which can be impacted by the ring spherical shell arc moving sliding block to slide back and forth, each outer ring spherical shell arc sliding block and the outer ring spherical shell sliding groove are fixedly provided with an outer ring spherical shell spring, each outer ring spherical shell is internally provided with an outer ring spherical shell hydraulic control channel communicated with the outer ring spherical shell sliding groove, and each outer ring spherical shell sliding groove and the outer ring spherical shell arc sliding block are fixedly provided with a sealing soft belt for sealing the outer ring spherical shell sliding groove.
Preferably, the outer ring spherical shell is fixedly provided with iron collecting control frames, the number of the iron collecting control frames is consistent with that of the arc-shaped long sliding grooves of the outer ring spherical shell, each iron collecting control frame and the outer ring spherical shell are provided with iron collecting sliding grooves of the iron collecting control frames, each iron collecting sliding groove of the iron collecting control frames is internally provided with an iron collecting sliding block capable of sliding in a reciprocating manner, each iron collecting sliding groove of the iron collecting control frames is internally and fixedly provided with an iron discharging limiting block for limiting the iron collecting sliding block, each iron collecting control frame is internally and fixedly provided with a liquid storage tank, each liquid storage tank is internally provided with a liquid storage cavity, each iron collecting control frame is provided with a hydraulic oil inlet pipe communicated with the upper part of the liquid storage tank, each iron collecting control frame is internally provided with an iron collecting hydraulic passage communicated with the liquid storage cavity and the iron collecting sliding grooves of the iron collecting control frames, each iron collecting control rack is provided with a hydraulic oil outlet pipe communicated with an iron collecting chute of the iron collecting control rack, each iron collecting control rack is fixedly provided with a hydraulic oil outlet communicated with the hydraulic oil outlet pipe, each iron collecting control rack is provided with an on-off control chute, each on-off control chute is internally provided with an on-off control slide block capable of sliding in a reciprocating manner, each on-off control slide block is provided with an on-off control upper through hole capable of switching on and off the iron collecting hydraulic channel, each on-off control slide block is provided with an on-off control lower through hole capable of switching on and off the hydraulic oil outlet pipe, and an on-off control spring is fixedly arranged between each on-off control chute and the on-off control slide block, and the outer ring spherical shell and each iron collecting control rack are provided with an on-off control hydraulic channel communicated with the on-off control sliding groove and the outer ring spherical shell hydraulic control channel.
Preferably, each iron collecting sliding block is provided with an iron collecting swing plate groove, each iron collecting sliding block is fixedly provided with an iron collecting swing shaft, each iron collecting swing shaft is provided with an iron collecting swing plate which can be freely and actively accommodated in the iron collecting swing plate groove, each iron collecting sliding block is internally provided with an iron discharge channel communicated with the iron collecting swing plate groove, each iron collecting control rack is internally and fixedly provided with an iron discharge pipe communicated with the iron discharge rail, the outer ring spherical shell and each iron collecting control rack are internally and fixedly provided with an iron discharge water inlet pipe, each iron collecting control rack is fixedly provided with an iron discharge water inlet communicated with the iron discharge water inlet pipe, and each iron collecting sliding block is provided with an iron discharge water inlet switching pipe which can be switched on and off along with the movement of the iron collecting sliding block and is communicated with the iron discharge water inlet switching pipe of the vertical rack.
Preferably, be equipped with the awl on the main pivot and turn, the awl is turned and is seted up the collection annular in, the awl is turned and has been seted up oblique minute groove, the awl is turned and is in the bin outlet has been seted up to the position of oblique minute groove, the awl is turned and is seted up row material automatically controlled fan-shaped spout, but be equipped with reciprocating sliding and break-make in arranging material automatically controlled fan-shaped spout the row of bin outlet fan-shaped automatically controlled slider, arrange material fan-shaped automatically controlled slider with arrange and set firmly between the automatically controlled fan-shaped spout of material and arrange material automatically controlled spring, the end frame has set firmly the rotation of weighing, it has the rotary chute of weighing to turn to set up in the weighing, set firmly in the main pivot can the rotary chute freely pivoted change of weighing.
Preferably, each vertical frame is provided with a plurality of control chutes, each control chute is internally provided with a control slide block capable of sliding in a reciprocating manner, each control slide block and a control spring are fixedly arranged between the control chutes, each control slide block is fixedly provided with a control slide rod extending out of the control chute, each control slide rod is fixedly provided with an upper control arc plate, the upper control arc plate is fixedly provided with an upper friction layer, the bevel gear ring is fixedly provided with a lower control arc plate, the lower control arc plate is fixedly provided with a lower friction layer capable of being abutted against the upper friction layer, and the vertical frame is provided with a control hydraulic port communicated with the control chutes.
Has the advantages that:
the invention provides a ceramic clay crushing and iron removing mechanism and a using method thereof through improvement, and compared with the prior art, the ceramic clay crushing and iron removing mechanism has the following improvements and advantages:
1. through the mutual cooperation of hammering moving axis, hammering fixed rod, hammering moving rod, last hammering ball layer, hammering ball pivot, clean dispersion movable arc slide, well hammering ball layer, lower hammering ball layer, can realize high-efficient breakage.
2. The iron removal and auxiliary grinding functions in the working state can be realized through the arc-shaped movable sliding block of the ring spherical shell and the arc-shaped long sliding groove of the outer ring spherical shell.
3. The periodic cleaning of the through holes of the inner ring spherical shell can be realized through the matching of the through hole cleaning sliding block, the through hole cleaning spring, the through hole cleaning sliding groove and the circular spherical shell arc movable sliding block, and the lowest discharge amount is ensured.
4. The automatic collection and removal of collected iron impurities can be realized through the matching of the arc-shaped movable sliding block of the ring spherical shell, the arc-shaped long sliding groove of the outer ring spherical shell, the iron collecting sliding block, the iron collecting swinging plate groove and other auxiliary structures.
5. The grinding granularity can be controlled by the upper control arc-shaped plate, the upper friction layer, the lower control arc-shaped plate, the control sliding groove, the control sliding block and the auxiliary mechanism thereof.
6. The separation of other density impurities can be realized through the cooperation of the cone rotating body, the collecting ring groove and the inclined separating groove.
Drawings
FIG. 1 is a flow chart of the design.
FIG. 2 is a front cross-sectional view of the present design;
FIG. 3 is a cross-sectional view taken at A-A of FIG. 2;
FIG. 4 is a cross-sectional view taken at B-B of FIG. 2;
FIG. 5 is a cross-sectional view taken at C-C of FIG. 2;
FIG. 6 is an enlarged view of a portion D of FIG. 2;
FIG. 7 is an enlarged view of a portion E of FIG. 2;
FIG. 8 is an enlarged view of a portion F of FIG. 2;
FIG. 9 is an enlarged view of a portion G of FIG. 2;
FIG. 10 is an enlarged view of a portion H of FIG. 3;
FIG. 11 is an enlarged view of a portion I of FIG. 3;
FIG. 12 is an enlarged view of a portion J of FIG. 10;
in the figure, a vertical rack 10, a rotating rack 11, a helical gear ring 12, an inner ring spherical shell 13, an inner ring spherical shell through hole 14, a cone rotator 15, a collecting ring groove 16, a skew dividing groove 17, a weighing rotator 18, a weighing rotator 19, a weighing rotator 20, a hammering moving rod 21, a hammering sliding groove 22, a hammering spring 23, a hammering fixing shaft 24, a hammering fixing shaft groove 25, a hammering moving shaft 26, a hammering fixing rod 27, a main rotating shaft 28, a separating strip 29, a helical gear ring groove 30, an outer ring spherical shell 31, an outer ring spherical shell through hole 32, a motor 33, a motor mounting groove 34, a bottom rack 35, a helical gear 36, a central arc block 37, a discharge port 38, a control sliding rod 39, a control sliding block 40, a control sliding groove 41, a control hydraulic pressure port 42, an upper control arc plate 43, an upper friction layer 44, a lower friction layer 45, a lower control arc plate 46, a hydraulic control spherical shell outer ring channel 47, an outer ring spherical shell sliding groove 48, an outer ring spherical shell spring 49, an outer ring spherical shell arc sliding block 50, a conical sliding groove 15, a conical groove, An outer ring spherical shell arc-shaped long chute 51, a cleaning dispersion movable arc-shaped sliding plate 52, a cleaning dispersion chute 53, an upper hammering ball layer 54, a hammering ball rotating shaft 55, a hammering hydraulic channel 56, a middle hammering ball layer 57, a cleaning dispersion hydraulic chute 58, a lower hammering ball layer 59, a cleaning dispersion hydraulic slider 60, a cleaning dispersion hydraulic spring 61, a cleaning dispersion hydraulic slider 62, a cleaning dispersion movable slider 63, a discharging fan-shaped electric control slider 64, a discharging electric control spring 65, a discharging electric control fan-shaped chute 66, a collision spring 67, a collision avoidance chute 68, a cleaning through hole chute 69, a cleaning through hole spring 70, a cleaning through hole slider 71, a ring spherical shell arc-shaped movable slider 72, a magnet 73, a collision avoidance head 74, a collision avoidance slider 75, an on-off control hydraulic channel 76, a liquid storage tank 77, an iron collection control rack 78, a hydraulic oil inlet 79, a hydraulic oil inlet pipe 80, a liquid storage cavity 81, an on-off control slider 82, and an on-off control upper through hole 83, The device comprises a hydraulic oil outlet pipe 84, a hydraulic oil outlet 85, an on-off control sliding groove 86, an on-off control spring 87, an on-off control lower through hole 88, an iron discharging water inlet 89, an iron discharging pipe 90, an iron discharging water inlet pipe 91, an iron discharging limiting block 92, an iron collecting hydraulic passage 93, an iron discharging water inlet adapter pipe 94, an iron collecting slide block 95, an iron collecting swing plate groove 96, an outer ring spherical shell iron collecting sliding groove 97, an iron collecting control rack iron collecting sliding groove 98, an iron collecting swing plate 99, an iron collecting swing shaft 100, an iron discharging railway 101, a control spring 102 and a sealing soft belt 103.
Detailed Description
The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.
In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.
As shown in fig. 2, a ceramic clay crushing and iron removing mechanism and a using method thereof are provided, the method is performed by matching with a ceramic clay crushing and iron removing mechanism, the ceramic clay crushing and iron removing mechanism comprises a bottom frame 35, vertical frames 10 are symmetrically and fixedly arranged on the bottom frame 35, a motor mounting groove 34 is formed on the bottom frame 35, a motor 33 is fixedly arranged in the motor mounting groove 34, a main rotating shaft 28 is fixedly arranged at an output end of the motor 33, an outer ring spherical shell 31 is fixedly arranged on the main rotating shaft 28, a plurality of outer ring spherical shell through holes 32 are uniformly formed on the outer ring spherical shell 31, a plurality of outer ring spherical shell arc long sliding chutes 51 are uniformly formed on the outer ring spherical shell 31, a ring spherical shell arc movable sliding block 72 capable of sliding back and forth is arranged in each outer ring spherical shell arc long sliding chute 51, an annular power transmission mechanism is fixedly arranged on the outer ring spherical shell 31, a hammering movable shaft 26 capable of rotating freely is fixedly arranged on the annular power transmission mechanism, the hammering movable shaft 26 is sleeved with a hammering fixed shaft 24 capable of freely rotating relatively, an inner ring spherical shell 13 is fixedly arranged on the hammering fixed shaft 24, a plurality of inner ring spherical shell through holes 14 are uniformly formed in the inner ring spherical shell 13, a hammering fixed rod 27 is fixedly arranged on the hammering movable shaft 26, a hammering sliding groove 22 is formed in the hammering fixed rod 27, a hammering moving rod 21 capable of sliding in a reciprocating mode is arranged in the hammering sliding groove 22, a hammering spring 23 is fixedly arranged between the hammering moving rod 21 and the hammering sliding groove 22, and an upper hammering ball layer 54 is fixedly arranged on the hammering moving rod 21.
As shown in fig. 2, 3 and 8, a hammering ball rotating shaft 55 capable of freely rotating is arranged on the upper hammering ball layer 54, a middle hammering ball layer 57 is fixedly arranged on the hammering ball rotating shaft 55, four cleaning dispersion chutes 53 are uniformly arranged on the middle hammering ball layer 57, a lower hammering ball layer 59 capable of freely rotating is arranged on the hammering ball rotating shaft 55, four cleaning dispersion hydraulic chutes 58 are uniformly arranged on the middle hammering ball layer 57, a cleaning dispersion hydraulic slide block 60 capable of freely sliding is arranged in each cleaning dispersion hydraulic chute 58, a cleaning dispersion hydraulic slide bar 62 extending out of the cleaning dispersion hydraulic chute 58 is fixedly arranged on each cleaning dispersion hydraulic slide block 60, a cleaning dispersion hydraulic spring 61 is fixedly arranged between each cleaning dispersion hydraulic slide block 60 and the cleaning dispersion hydraulic chute 58, a cleaning dispersion slide block 63 capable of reciprocating sliding in the cleaning dispersion chute 53 is fixedly arranged on each cleaning dispersion hydraulic slide bar 62, each cleaning dispersion sliding block 63 is fixedly provided with a cleaning dispersion movable arc-shaped sliding plate 52, the inner wall of the inner ring spherical shell 13 is fixedly provided with a separating strip 29 which can be matched and crushed with the middle hammering ball layer 57 and the lower hammering ball layer 59, and hammering hydraulic channels 56 which are communicated with the cleaning dispersion hydraulic sliding grooves 58 and the hammering sliding grooves 22 are fixedly arranged in the hammering movable rod 21, the upper hammering ball layer 54, the hammering ball rotating shaft 55 and the middle hammering ball layer 57.
As shown in fig. 2 and 3, the annular power transmission mechanism includes an outer ring spherical shell 31, a rotating frame 11 is fixedly arranged on the outer ring spherical shell 31, a helical gear ring 12 is fixedly arranged on the rotating frame 11, a helical gear ring groove 30 is formed in the helical gear ring 12, helical gears 36 capable of being in meshing transmission are symmetrically arranged in the helical gear ring groove 30, hammering movable shafts 26 are fixedly arranged between the helical gears 36, and hammering shaft fixing grooves 25 capable of helping an upper hammering ball layer 54, a middle hammering ball layer 57 and a lower hammering ball layer 59 to be broken are formed in the hammering shaft fixing 24.
As shown in the figures 2 and 3, the above-mentioned figures, 11, a central arc block 37 abutting against the inner ring spherical shell 13 is fixedly arranged on the outer ring spherical shell 31, anti-collision sliding grooves 68 with the same number as that of the ring spherical shell arc movable sliding blocks 72 are formed in the central arc block 37, anti-collision sliding rods 75 capable of sliding back and forth in each anti-collision sliding groove 68 are fixedly arranged between each anti-collision sliding rod 75 and each anti-collision sliding groove 68, anti-collision heads 74 capable of sealing the anti-collision sliding grooves 68 and abutting against the ring spherical shell arc movable sliding blocks 72 are fixedly arranged on each anti-collision sliding rod 75, anti-collision heads 74 capable of absorbing iron chips are fixedly arranged on each ring spherical shell arc movable sliding blocks 72, a plurality of cleaning through hole sliding grooves 69 are formed in each ring spherical shell arc movable sliding block 72, cleaning through hole sliding blocks 71 capable of sliding back and forth and capable of cleaning the through holes 14 of the inner ring spherical shell are arranged in each cleaning through hole sliding block 69, and cleaning through hole springs 70 are fixedly arranged between each cleaning through hole sliding block 71 and each cleaning through hole sliding block 69.
As shown in fig. 7, the outer ring spherical shell 31 is uniformly provided with outer ring spherical shell chutes 48 having the same number as the outer ring spherical shell arc long chutes 51, each outer ring spherical shell chute 48 is provided with an outer ring spherical shell arc slide block 50 capable of being impacted by the ring spherical shell arc slide block 72 to slide back and forth, an outer ring spherical shell spring 49 is fixedly arranged between each outer ring spherical shell arc slide block 50 and the outer ring spherical shell chute 48, each outer ring spherical shell 31 is provided with an outer ring spherical shell hydraulic control passage 47 communicated with the outer ring spherical shell chute 48, and a sealing soft belt 103 for sealing the outer ring spherical shell chute 48 is fixedly arranged between each outer ring spherical shell chute 48 and the outer ring spherical shell arc slide block 50.
As shown in fig. 10, the outer ring spherical shell 31 is fixedly provided with iron collecting control frames 78 whose number is consistent with that of the outer ring spherical shell arc-shaped long chutes 51, each iron collecting control frame 78 and the outer ring spherical shell 31 are provided with iron collecting control frame iron collecting chutes 98, each iron collecting control frame iron collecting chute 98 is internally provided with an iron collecting slide block 95 capable of sliding back and forth, each iron collecting control frame iron collecting chute 98 is internally and fixedly provided with an iron discharging limiting block 92 for limiting the iron collecting slide block 95, each iron collecting control frame 78 is internally and fixedly provided with a liquid storage tank 77, each liquid storage tank 77 is internally provided with a liquid storage cavity 81, each iron collecting control frame 78 is provided with a hydraulic oil inlet pipe 80 communicated with the upper part of the liquid storage tank 77, each iron collecting control frame 78 is fixedly provided with a hydraulic oil inlet 79 communicated with the hydraulic oil inlet pipe 80, each iron collecting control frame 78 is internally provided with an iron collecting hydraulic passage 93 communicating the liquid storage cavity 81 with the iron collecting control frame iron collecting chutes 98, each iron collecting control frame 78 is provided with a hydraulic oil outlet pipe 84 communicated with an iron collecting chute 98 of the iron collecting control frame, each iron collecting control frame 78 is fixedly provided with a hydraulic oil outlet 85 communicated with the hydraulic oil outlet pipe 84, each iron collecting control frame 78 is provided with an on-off control chute 86, each on-off control chute 86 is internally provided with an on-off control slide block 82 capable of sliding in a reciprocating manner, each on-off control slide block 82 is provided with an on-off control upper through hole 83 capable of opening and closing an iron collecting hydraulic channel 93, each on-off control slide block 82 is provided with an on-off control lower through hole 88 capable of opening and closing the hydraulic oil outlet pipe 84, an on-off control spring 87 is fixedly arranged between each on-off control chute 86 and the on-off control slide block 82, and the outer ring spherical shell 31 and each iron collecting control frame 78 are provided with an on-off control hydraulic channel 76 communicated with the on-off control chute 86 and the outer ring spherical shell hydraulic channel 47.
As shown in fig. 12, each iron receiving slider 95 is provided with an iron receiving swing plate groove 96, each iron receiving slider 95 is fixedly provided with an iron receiving swing shaft 100 in the iron receiving swing plate groove 96, each iron receiving swing shaft 100 is provided with an iron receiving swing plate 99 which can be freely and actively accommodated in the iron receiving swing plate groove 96, each iron receiving slider 95 is provided with an iron discharge channel 101 communicated with the iron receiving swing plate groove 96, each iron receiving control rack 78 is fixedly provided with an iron discharge pipe 90 communicated with the iron discharge pipe 101, the outer ring spherical shell 31 and each iron receiving control rack 78 are fixedly provided with an iron discharge water inlet pipe 91, each iron receiving control rack 78 is fixedly provided with an iron discharge water inlet 89 communicated with the iron discharge water inlet pipe 91, and each iron receiving slider 95 is provided with an iron discharge water adapter pipe 94 capable of being connected with the iron receiving slider 95 and disconnected with the iron discharge water inlet pipe 91 of the vertical rack 10 along with movement.
As shown in fig. 4 and 9, the main rotating shaft 28 is provided with a cone rotator 15, a collecting ring groove 16 is formed in the cone rotator 15, the cone rotator 15 is provided with an oblique dividing groove 17, the cone rotator 15 is provided with a discharge port 38 at the position of the oblique dividing groove 17, a discharge electric control fan-shaped chute 66 is formed in the cone rotator 15, a discharge fan-shaped electric control slider 64 which can slide in a reciprocating manner and can open and close the discharge port 38 is arranged in the discharge electric control fan-shaped chute 66, a discharge electric control spring 65 is fixedly arranged between the discharge fan-shaped electric control slider 64 and the discharge electric control fan-shaped chute 66, the bottom frame 35 is fixedly provided with the weighing rotator 18, a weighing rotator groove 19 is formed in the weighing rotator 18, and a weighing rotator 20 which can rotate freely in the weighing rotator groove 19 is fixedly arranged on the main rotating shaft 28.
As shown in fig. 2, 3, and 6, each vertical frame 10 is provided with a plurality of control chutes 41, each control chute 41 is provided with a control slider 40 capable of sliding back and forth, a control spring 102 is fixedly arranged between each control slider 40 and the control chute 41, each control slider 40 is fixedly provided with a control slide bar 39 extending out of the control chute 41, each control slide bar 39 is fixedly provided with an upper control arc 43, the upper control arc 43 is fixedly provided with an upper friction layer 44, the helical gear ring 12 is fixedly provided with a lower control arc 46, the lower control arc 46 is fixedly provided with a lower friction layer 45 capable of abutting against the upper friction layer 44, and the vertical frame 10 is provided with a control hydraulic port 42 communicated with the control chute 41.
Initial position: the control chute 41 is internally provided with hydraulic oil with certain pressure, and pushes the control slide block 40 to overcome the resistance of the vertical frame 10, so as to drive the control slide rod 39 to push the upper control arc-shaped plate 43, and the upper friction layer 44 is abutted to the lower friction layer 45. The hydraulic oil inlet 79 and the hydraulic oil outlet 85 are externally connected with a hydraulic control system, and the iron discharging water inlet 89 is connected with a water injection hose. The on-off control slide block 82 is driven by an on-off control spring 87 to block the iron collecting hydraulic channel 93 and connect the hydraulic oil outlet pipe 84. The arc-shaped movable sliding blocks 72 of the ring ball shell are all abutted with the anti-collision heads 74. The upper hammer ball layer 54, the middle hammer ball layer 57 and the lower hammer ball layer 59 are located at the bottom of the inner ring ball shell 13. The discharge opening 38 is driven by a discharge electric control spring 65 to block the discharge opening 38. Hydraulic oil is provided in the hammering slide groove 22. The rotation speed of the motor 33 is periodically changed. The outer ring spherical shell sliding groove 48 and the outer ring spherical shell hydraulic control channel 47 are filled with hydraulic oil. The hydraulic oil in the reservoir chamber 81 is always kept at a high level. The end of the iron expulsion tube 90 is placed into a debris collection bucket (not shown).
This deironing mechanism is smashed to ceramic clay's specific application step as follows:
the first step is as follows: and (4) feeding. The material is thrown into the inner race spherical shell 13.
The second step is that: crushing the raw materials. The motor 33 is started by power, the motor 33 drives the main rotating shaft 28 to rotate, the cleaning and dispersing hydraulic chute 58 drives the outer ring spherical shell 31 to rotate, the outer ring spherical shell 31 drives the rotating rack 11 to rotate, and the control slide block 40 is pushed to overcome the resistance of the vertical rack 10 due to the fact that hydraulic oil with certain pressure is arranged in the control chute 41, so that the control slide rod 39 is driven to push the upper control arc-shaped plate 43, and the upper friction layer 44 is enabled to be abutted to the lower friction layer 45. Therefore, the hammering fixing shaft 24 and the hammering moving shaft 26 on the inner ring spherical shell 13 drive the helical gear 36 to rotate anticlockwise in the helical gear ring groove 30 of the helical gear ring 12 at a speed different from the outer ring spherical shell 31. Due to the rotation of the hammering moving shaft 26, the separating strip 29 drives the hammering fixing rod 27 to rotate, the hammering fixing rod 27 drives the hammering moving rod 21 to rotate, the hammering moving rod 21 drives the upper hammering ball layer 54 to rotate, the upper hammering ball layer 54 drives the hammering ball rotating shaft 55 to rotate, and the hammering ball rotating shaft 55 drives the middle hammering ball layer 57 and the lower hammering ball layer 59 to rotate. The upper hammering ball layer 54, the hammering ball rotating shaft 55, the middle hammering ball layer 57 and the lower hammering ball layer 59 are enabled to abut against the separating strip 29 along with the rotation of the upper hammering ball layer, under the action of the separating strip 29, the hammering moving rod 21 overcomes the resistance of the hammering spring 23, enters the hammering sliding groove 22 and extrudes hydraulic oil in the hammering sliding groove 22 to enter a hammering hydraulic channel 56, the hydraulic oil enters a cleaning dispersion hydraulic sliding groove 58 through the hammering hydraulic channel 56, then the cleaning dispersion hydraulic sliding rod 62 is pushed and driven to extend outwards by overcoming the resistance of the cleaning dispersion hydraulic spring 61, the cleaning dispersion hydraulic sliding rod 62 drives the cleaning dispersion sliding block 63 to slide in the cleaning dispersion sliding groove 53, and meanwhile, the cleaning dispersion arc-shaped sliding plate 52 is pushed to move outwards. During this process, the material is stirred to some extent, crushed to some extent, and the outer surfaces of the upper hammer ball layer 54, the dispersion arc slide plate 52 and the lower hammer ball layer 59 are cleaned. Along with the rotation of the upper hammering ball layer 54, the hammering ball rotating shaft 55, the middle hammering ball layer 57 and the lower hammering ball layer 59, the abutting joint of the upper hammering ball layer and the separating strip 29 is released, under the action of the cleaning dispersion hydraulic spring 61, the cleaning dispersion hydraulic slide block 60 drives the cleaning dispersion hydraulic slide block 62, the cleaning dispersion hydraulic slide block 62 drives the cleaning dispersion movable slide block 63, the cleaning dispersion movable slide block 63 drives the cleaning dispersion movable arc-shaped slide plate 52 to retract, and under the cooperation of the hammering spring 23, the hydraulic oil in the cleaning dispersion hydraulic chute 58 returns to the hammering chute 22 through the hammering hydraulic passage 56. With the continuous rotation of the hammering movable shaft 26, after the hammering fixed rod 27 drives the hammering movable rod 21 to cross the center, the hammering fixed rod 27 and the hammering movable rod 21 which lose the limitation of the hammering fixed shaft groove 25 drive the upper hammering ball layer 54, the middle hammering ball layer 57 and the lower hammering ball layer 59 to fall down quickly, and possible large clay blocks are hammered. In the process of finding one more, the upper hammering ball layer 54, the hammering ball rotating shaft 55, the middle hammering ball layer 57 and the lower hammering ball layer 59 rotate to enable the upper hammering ball layer, the middle hammering ball layer and the lower hammering ball layer to be abutted against the separating strip 29, under the action of the separating strip 29, the hammering moving rod 21 overcomes the resistance of the hammering spring 23 to enter the hammering sliding groove 22 and extrude hydraulic oil in the hammering sliding groove into the hammering hydraulic channel 56, the hydraulic oil enters the cleaning dispersion hydraulic sliding groove 58 through the hammering hydraulic channel 56, then the cleaning dispersion hydraulic sliding rod 62 is pushed and driven to extend outwards by overcoming the resistance of the cleaning dispersion hydraulic spring 61, the cleaning dispersion hydraulic sliding rod 62 drives the cleaning dispersion sliding block 63 to slide in the cleaning dispersion sliding groove 53, and meanwhile the cleaning dispersion arc-shaped sliding plate 52 is pushed to move outwards. Along with the rotation of the upper hammering ball layer 54, the hammering ball rotating shaft 55, the middle hammering ball layer 57 and the lower hammering ball layer 59, the abutting joint of the upper hammering ball layer and the separating strip 29 is released, under the action of the cleaning dispersion hydraulic spring 61, the cleaning dispersion hydraulic slide block 60 drives the cleaning dispersion hydraulic slide block 62, the cleaning dispersion hydraulic slide block 62 drives the cleaning dispersion movable slide block 63, the cleaning dispersion movable slide block 63 drives the cleaning dispersion movable arc-shaped slide plate 52 to retract, and under the cooperation of the hammering spring 23, the hydraulic oil in the cleaning dispersion hydraulic chute 58 returns to the hammering chute 22 through the hammering hydraulic passage 56. The crushed particles enter a gap between the inner ring spherical shell 13 and the outer ring spherical shell 31 through the inner ring spherical shell through hole 14 on the collecting ring groove 16.
The third step: grinding the raw materials. The hammering fixing shaft 24 and the hammering moving shaft 26 on the inner ring spherical shell 13 drive the helical gear 36 to rotate anticlockwise in the helical gear ring groove 30 of the helical gear ring 12, wherein the rotating speed of the helical gear ring is inconsistent with that of the outer ring spherical shell 31. And the crushed particles have entered the gap between the inner ring spherical shell 13 and the outer ring spherical shell 31 via the inner ring spherical shell through-hole 14 in the collecting ring groove 16. With the rotation of the inner ring spherical shell 13 and the outer ring spherical shell 31, the raw material between the gaps is continuously ground and crushed.
The fourth step: removing iron and discharging iron-containing impurities. With the active rotation of the outer ring spherical shell 31, the ring spherical shell arc-shaped movable slider 72 moves upwards along the outer ring spherical shell arc-shaped long sliding groove 51 under the comprehensive action of force, and in the moving process, the magnet 73 absorbs iron-containing impurities between the inner ring spherical shell 13 and the outer ring spherical shell 31. When the ring spherical shell arc-shaped movable sliding block 72 moves upwards along the outer ring spherical shell arc-shaped long sliding groove 51 to touch the outer ring spherical shell arc-shaped sliding block 50, the outer ring spherical shell arc-shaped sliding block 50 is pushed to overcome the resistance of the outer ring spherical shell spring 49, hydraulic oil in the outer ring spherical shell sliding groove 48 is extruded, hydraulic oil in the outer ring spherical shell hydraulic control channel 47 is extruded to enter the on-off control hydraulic channel 76, the on-off control sliding block 82 is pushed to overcome the resistance of the on-off control spring 87,
and the sliding is carried out, the on-off control upper through hole 83 is communicated with the iron-receiving hydraulic channel 93, and the on-off control sliding block 82 blocks the hydraulic oil outlet pipe 84. Hydraulic oil in the liquid storage cavity 81 enters the iron receiving chute 98 of the iron receiving control rack through the iron receiving hydraulic passage 93, then the iron receiving slide block 95 is pushed to move in the iron receiving chute 98 of the iron receiving control rack, the iron receiving slide block 95 enters a space between the inner ring spherical shell 13 and the outer ring spherical shell 31 through the outer ring spherical shell iron receiving chute 97, the iron receiving swing plate 99 is opened under the action of gravity, and in the process, iron-containing impurities adsorbed by the magnet 73 are scraped. When the rotation speed of the motor 33 changes, the ring spherical shell arc-shaped movable slider 72 slides downwards along the outer ring spherical shell arc-shaped long chute 51 under the action of gravity, the ring spherical shell arc-shaped movable slider 72 relieves the extrusion of the outer ring spherical shell arc-shaped slider 50 on the outer ring spherical shell arc-shaped slider 50 under the action of the outer ring spherical shell spring 49, hydraulic oil in the outer ring spherical shell hydraulic channel 47 and the outer ring spherical shell chute 48 is sucked to restore the original position, the hydraulic oil exits the on-off control chute 86 through the on-off control hydraulic channel 76, and the on-off control slider 82 blocks the iron collecting hydraulic channel 93 from being communicated with the hydraulic oil outlet pipe 84 under the drive of the on-off control spring 87. The hydraulic oil in the iron collecting chute 98 of the iron collecting control frame is discharged through the hydraulic oil outlet pipe 84. The iron collecting slide block 95 retracts into the iron collecting chute 98 of the iron collecting control rack under the action of gravity, the iron collecting swing plate 99 also returns into the iron collecting swing plate groove 96, the iron discharging water inlet adapter tube 94 and the iron discharging water inlet tube 91 are connected, meanwhile, the iron-containing impurities are stacked on the upper port of the iron discharging channel 101, at the moment, water enters the iron discharging water inlet tube 91 through the iron discharging water inlet 89 and enters the iron discharging water inlet adapter tube 94, and then enters the iron discharging channel 101 through the iron discharging water inlet adapter tube 94 to discharge the iron-containing impurities through the iron discharging tube 90.
The fifth step: screening for other impurities. The clay particles after being ground and deironing enter the interior of the cone rotator 15 through the outer ring spherical shell through hole 32 of the outer ring spherical shell 31. The cone rotator 15 is vibrated by the main rotating shaft 28. During the rotation, due to the different densities, other impurity particles enter the collecting ring groove 16 through the inclined dividing groove 17 to be stored.
And a sixth step: discharging. The discharging fan-shaped electric control slide block 64 is controlled to overcome the resistance of the discharging electric control spring 65 to open the discharging port 38, and the clay existing in the cone rotator 15 is discharged.
The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.
Claims (9)
1. A ceramic clay crushing and iron removing mechanism and a using method thereof are provided, the method is carried out by matching with a ceramic clay crushing and iron removing mechanism, the ceramic clay crushing and iron removing mechanism comprises a bottom rack (35), vertical racks (10) are symmetrically and fixedly arranged on the bottom rack (35), a motor mounting groove (34) is formed in the bottom rack (35), a motor (33) is fixedly arranged in the motor mounting groove (34), a main rotating shaft (28) is fixedly arranged at the output end of the motor (33), an outer ring spherical shell (31) is fixedly arranged on the main rotating shaft (28), a plurality of outer ring spherical shell through holes (32) are uniformly formed in the outer ring spherical shell (31), a plurality of outer ring spherical shell arc long sliding chutes (51) are uniformly formed in the outer ring spherical shell arc long sliding chutes (51), and a ring spherical shell arc movable sliding block (72) capable of sliding in a reciprocating manner is arranged in each outer ring spherical shell arc long sliding chute (51), set firmly annular power transmission mechanism on outer lane spherical shell (31), but set firmly free pivoted hammering moving axis (26) on the annular power transmission mechanism, the cover is equipped with solid axle (24) of free pivoted hammering relatively on hammering moving axis (26), inner circle spherical shell (13) have set firmly on the solid axle of hammering (24), evenly seted up a plurality of inner circle spherical shell through-holes (14) on inner circle spherical shell (13), pole (27) are decided to the hammering having set firmly on hammering moving axis (26), hammering spout (22) have been seted up on the pole (27) are decided to the hammering, but be equipped with reciprocating sliding's hammering in hammering spout (22) and move pole (21), hammering move pole (21) with hammering spring (23) have set firmly between hammering spout (22), hammering moves and has set firmly hammering ball layer (54) on pole (21).
2. The ceramic clay pulverizing and iron removing mechanism and the use method thereof according to claim 1, wherein the ceramic clay pulverizing and iron removing mechanism comprises: the upper hammering ball layer (54) is provided with a hammering ball rotating shaft (55) capable of freely rotating, the hammer hammering ball rotating shaft (55) is fixedly provided with a middle hammering ball layer (57), the middle hammering ball layer (57) is uniformly provided with four cleaning and dispersing sliding chutes (53), the hammer hammering ball rotating shaft (55) is provided with a lower hammering ball layer (59) capable of freely rotating, the middle hammering ball layer (57) is uniformly provided with four cleaning and dispersing hydraulic sliding chutes (58), each cleaning and dispersing hydraulic sliding chute (58) is internally provided with a cleaning and dispersing hydraulic sliding block (60) capable of freely sliding, each cleaning and dispersing hydraulic sliding block (60) is fixedly provided with a cleaning and dispersing hydraulic sliding rod (62) extending out of the cleaning and dispersing hydraulic sliding chute (58), and a cleaning and dispersing hydraulic spring (61) is fixedly arranged between each cleaning and dispersing hydraulic sliding block (60) and the cleaning and dispersing hydraulic sliding chute (58), each cleaning dispersion hydraulic sliding rod (62) is fixedly provided with a cleaning dispersion movable sliding block (63) capable of sliding in a reciprocating manner in the cleaning dispersion sliding groove (53), each cleaning dispersion movable sliding block (63) is fixedly provided with a cleaning dispersion movable arc-shaped sliding plate (52), the inner wall of the inner ring ball shell (13) is fixedly provided with a separating strip (29) capable of being matched and broken with the middle hammering ball layer (57) and the lower hammering ball layer (59), the hammering movable rod (21), the upper hammering ball layer (54), the hammering ball hitting rotating shaft (55) and the middle hammering ball layer (57) are internally and fixedly provided with hammering hydraulic channels (56) communicated with the cleaning dispersion hydraulic sliding groove (58) and the hammering sliding groove (22).
3. The ceramic clay pulverizing and iron removing mechanism and the use method thereof according to claim 1, wherein the ceramic clay pulverizing and iron removing mechanism comprises: annular power transmission mechanism includes outer lane spherical shell (31), change frame (11) has set firmly on outer lane spherical shell (31), change frame (11) and set firmly helical gear ring (12), helical gear ring (30) have been seted up on helical gear ring (12), helical gear ring (30) internal symmetry is equipped with driven helical gear (36) that can mesh, hammering moving axis (26) has set firmly jointly between helical gear (36), it can help to have seted up on hammering solid axle (24) go up hammering ball layer (54), well hammering ball layer (57) and lower hammering solid shaft groove (25) of the broken hammering of ball layer (59).
4. The ceramic clay pulverizing and iron removing mechanism and the use method thereof according to claim 1, wherein the ceramic clay pulverizing and iron removing mechanism comprises: the utility model discloses a ball shell structure, including outer lane ball shell (31) set firmly the butt in the central arc piece (37) of inner circle ball shell (13), set up on central arc piece (37) with circle ball shell arc moves crashproof spout (68) that slider (72) quantity is unanimous, every can reciprocating sliding crashproof slide bar (75) in crashproof spout (68), every crashproof slide bar (75) with anticollision spring (67) have set firmly between crashproof spout (68), every be set firmly on crashproof slide bar (75) and seal crashproof spout (68) and can with circle ball shell arc moves crashproof head (74) of slider (72) butt, every circle ball shell arc moves and sets firmly crashproof head (74) that can absorb iron fillings on slider (72), every a plurality of clean through-hole spouts (69) have been seted up on circle ball shell arc moves slider (72), every be equipped with reciprocating sliding and can clear up in clean through-hole spout (69) inner circle ball shell through-hole (14) ) The cleaning through hole sliding blocks (71) are provided with cleaning through hole springs (70) fixedly arranged between each cleaning through hole sliding block (71) and the cleaning through hole sliding groove (69).
5. The ceramic clay pulverizing and iron removing mechanism and the use method thereof according to claim 1, wherein the ceramic clay pulverizing and iron removing mechanism comprises: outer lane spherical shell (31) evenly seted up with the long spout of outer lane spherical shell arc (51) unanimous outer lane spherical shell spout (48) of quantity, every be equipped with in outer lane spherical shell spout (48) can by circle spherical shell arc moves slider (72) striking and reciprocating sliding's outer lane spherical shell arc slider (50), every outer lane spherical shell arc slider (50) with outer lane spherical shell spring (49) have set firmly between outer lane spherical shell spout (48), every set up in outer lane spherical shell (31) with outer lane spherical shell hydraulic control way (47) of outer lane spherical shell spout (48) intercommunication, every outer lane spherical shell spout (48) with set firmly between outer lane spherical shell arc slider (50) and seal sealed soft area (103) of outer lane spherical shell spout (48).
6. The ceramic clay pulverizing and iron removing mechanism and the use method thereof according to claim 1, wherein the ceramic clay pulverizing and iron removing mechanism comprises: the outer ring spherical shell (31) is fixedly provided with iron collecting control frames (78) the number of which is consistent with that of the arc-shaped long sliding grooves (51) of the outer ring spherical shell, each iron collecting control frame (78) and the outer ring spherical shell (31) are provided with iron collecting control frame iron collecting sliding grooves (98), each iron collecting control frame iron collecting sliding groove (98) is internally provided with an iron collecting sliding block (95) capable of sliding in a reciprocating manner, each iron collecting control frame iron collecting sliding groove (98) is internally and fixedly provided with an iron discharging limiting block (92) limiting the iron collecting sliding block (95), each iron collecting control frame (78) is internally and fixedly provided with a liquid storage tank (77), each liquid storage tank (77) is internally provided with a liquid storage cavity (81), each iron collecting control frame (78) is provided with a hydraulic oil inlet pipe (80) communicated with the upper part of the liquid storage tank (77), each iron collecting control frame (78) is fixedly provided with a hydraulic oil inlet (79) communicated with the hydraulic oil inlet pipe (80), an iron collecting hydraulic channel (93) communicated with the liquid storage cavity (81) and an iron collecting sliding groove (98) of the iron collecting control rack is formed in each iron collecting control rack (78), a hydraulic oil outlet pipe (84) communicated with the iron collecting sliding groove (98) of the iron collecting control rack is formed in each iron collecting control rack (78), a hydraulic oil outlet (85) communicated with the hydraulic oil outlet pipe (84) is fixedly arranged on each iron collecting control rack (78), an on-off control sliding groove (86) is formed in each iron collecting control rack (78), an on-off control sliding block (82) capable of sliding in a reciprocating mode is arranged in each on-off control sliding groove (86), an on-off control upper through hole (83) capable of switching on and off the iron collecting hydraulic channel (93) is formed in each on-off control sliding block (82), and an on-off control lower through hole (88) capable of switching on and off the hydraulic oil outlet pipe (84) is formed in each on the on-off control sliding block (82), an on-off control spring (87) is fixedly arranged between each on-off control sliding groove (86) and each on-off control sliding block (82), and an on-off control hydraulic channel (76) communicated with the on-off control sliding groove (86) and the outer ring spherical shell hydraulic channel (47) is formed in each outer ring spherical shell (31) and each iron collecting control rack (78).
7. The ceramic clay pulverizing and iron removing mechanism and the use method thereof as claimed in claim 6, wherein: each iron receiving sliding block (95) is provided with an iron receiving swing plate groove (96), each iron receiving sliding block (95) is arranged in the iron receiving swing plate groove (96) and is fixedly provided with an iron receiving swing shaft (100), each iron receiving swing shaft (100) is provided with an iron receiving swing plate (99) which can be freely and actively accommodated in the iron receiving swing plate groove (96), each iron receiving sliding block (95) is internally provided with an iron discharging pipe (101) communicated with the iron receiving swing plate groove (96), each iron receiving control rack (78) is internally and fixedly provided with an iron discharging pipe (90) communicated with the iron discharging pipe (101), each outer ring spherical shell (31) and each iron receiving control rack (78) are internally and fixedly provided with an iron discharging water inlet pipe (91), each iron receiving control rack (78) is fixedly provided with an iron discharging water inlet (89) communicated with the iron discharging water inlet pipe (91), and each iron receiving sliding block (95) is provided with an iron discharging water inlet pipe (91) and a vertical iron discharging water inlet pipe (91) communicated with the iron receiving sliding block (95) along with the iron receiving sliding block (95) The iron discharging water inlet adapter tube (94) of the frame (10).
8. The ceramic clay pulverizing and iron removing mechanism and the use method thereof according to claim 1, wherein the ceramic clay pulverizing and iron removing mechanism comprises: a cone rotating body (15) is arranged on the main rotating shaft (28), a collecting ring groove (16) is arranged in the cone rotating body (15), the cone rotating body (15) is provided with an inclined dividing groove (17), the cone rotating body (15) is provided with a discharge hole (38) at the position of the inclined dividing groove (17), a discharging electric control fan-shaped chute (66) is arranged in the cone rotating body (15), a discharging fan-shaped electric control sliding block (64) which can slide in a reciprocating way and can switch on and off the discharging opening (38) is arranged in the discharging electric control fan-shaped chute (66), a discharging electric control spring (65) is fixedly arranged between the discharging fan-shaped electric control slide block (64) and the discharging electric control fan-shaped chute (66), a weighing rotating body (18) is fixedly arranged on the bottom rack (35), a weighing rotating groove (19) is arranged in the weighing rotating body (18), and a weighing rotating ring (20) which can freely rotate in the weighing rotating groove (19) is fixedly arranged on the main rotating shaft (28).
9. The ceramic clay pulverizing and iron removing mechanism and the use method thereof according to claim 1, wherein the ceramic clay pulverizing and iron removing mechanism comprises: each vertical rack (10) is provided with a plurality of control chutes (41), each control chute (41) is internally provided with a control slide block (40) capable of sliding in a reciprocating manner, a control spring (102) is fixedly arranged between each control slide block (40) and the control chute (41), each control slide block (40) is fixedly provided with a control slide rod (39) extending out of the control chute (41), each control slide rod (39) is fixedly provided with an upper control arc-shaped plate (43), an upper friction layer (44) is fixedly arranged on the upper arc control plate (43), a lower arc control plate (46) is fixedly arranged on the bevel gear ring (12), a lower friction layer (45) which can be abutted against the upper friction layer (44) is fixedly arranged on the lower control arc-shaped plate (46), and a control hydraulic port (42) communicated with the control sliding groove (41) is formed in the vertical rack (10).
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| CN112570129A (en) * | 2020-12-15 | 2021-03-30 | 余荣安 | Multi-screening reinforced concrete crusher and using method thereof |
| CN113680455A (en) * | 2021-08-21 | 2021-11-23 | 郑长顺 | Environment-friendly construction waste rubbing crusher |
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| CN112570129A (en) * | 2020-12-15 | 2021-03-30 | 余荣安 | Multi-screening reinforced concrete crusher and using method thereof |
| CN113680455A (en) * | 2021-08-21 | 2021-11-23 | 郑长顺 | Environment-friendly construction waste rubbing crusher |
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| CN114178021B (en) | 2023-07-07 |
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Effective date of registration: 20230608 Address after: 521000 Fengxi Fenger management zone, Chaozhou City, Guangdong Province Applicant after: GUANGDONG DONGBAO GROUP Co.,Ltd. Address before: 457399 21 Wenhua Road East, Qingfeng County, Puyang City, Henan Province Applicant before: Zhang Chaolu |
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Denomination of invention: A ceramic clay crushing iron removal mechanism and its usage method Effective date of registration: 20231214 Granted publication date: 20230707 Pledgee: Industrial and Commercial Bank of China Limited Chaozhou Branch Pledgor: GUANGDONG DONGBAO GROUP Co.,Ltd. Registration number: Y2023980071631 |