CN219596716U - Efficient sound awl and breaker - Google Patents
Efficient sound awl and breaker Download PDFInfo
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- CN219596716U CN219596716U CN202320784399.1U CN202320784399U CN219596716U CN 219596716 U CN219596716 U CN 219596716U CN 202320784399 U CN202320784399 U CN 202320784399U CN 219596716 U CN219596716 U CN 219596716U
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- cone
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- 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
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W30/00—Technologies for solid waste management
- Y02W30/50—Reuse, recycling or recovery technologies
- Y02W30/62—Plastics recycling; Rubber recycling
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Abstract
The utility model discloses a high-efficiency dynamic and static cone, which consists of a dynamic cone and a static cone, wherein the dynamic cone comprises a dynamic cone main body and a plurality of dynamic cone composite areas, and the dynamic cone composite areas are positioned on the conical surface of the dynamic cone; the static cone comprises a static cone main body and a plurality of static cone composite areas, and the static cone composite areas are positioned on the inner inclined surface of the static cone main body; a movable cone interval is formed between two adjacent movable cone composite regions, and a static cone interval is formed between two adjacent static cone composite regions; the movable cone composite region and the static cone composite region are both composed of ceramic particles and a metal matrix and are wavy; the movable cone interval and the static cone interval are both made of metal; the movable cone interval corresponds to the position of the static cone composite region, and the static cone interval corresponds to the position of the movable cone composite region. The utility model can reduce material slipping, can gather materials, and greatly improves crushing efficiency.
Description
Technical Field
The utility model relates to a high-efficiency dynamic and static cone and a crusher, and belongs to the technical field of industrial dynamic and static cones.
Background
The cone crusher is a machine widely applied to raw material crushing in metallurgical, building, road building, chemical and silicate industries, is suitable for medium crushing and fine crushing of various ores and rocks, and has uniform product granularity.
The dynamic cone and the static cone in the cone crusher are main structures of the crushing function, and the performances of the dynamic cone and the static cone relate to the granularity of a final product, so that the production efficiency is affected. The dynamic cone and the static cone are the most main wearing parts in the cone machine, and once the dynamic cone and the static cone are worn and have faults, the granularity of the product can be influenced; the sliding of the materials between the movable cone and the static cone is also one of the influencing factors of the granularity of the product.
Chinese patent (CN 108514914 a) discloses a two-stage crushing cone crusher, an eccentric mechanism is mounted at the inner end of the transmission mechanism, and a movable cone is fixed at the top of the eccentric mechanism; a movable cone lining plate is fixed on the side surface of the movable cone; the inner side of the static cone is fixed with a static cone lining board. The eccentric wheel of the eccentric mechanism drives the movable cone to perform eccentric motion through the eccentric shaft, so that the movable cone lining plate is close to the static cone lining plate, and materials are crushed by multiple extrusion and impact of the movable cone and the static cone. The material between the movable cone lining board and the static cone lining board in the scheme is easy to slip, needs to be repeatedly crushed, and has low efficiency. The wear easily occurs in the long-term use process to generate fracture, frequent replacement is needed, the production efficiency is affected, and the cost is increased.
Disclosure of Invention
The utility model provides a high-efficiency dynamic and static cone, which solves the problem that materials between the dynamic and static cones are easy to slide in the prior art.
In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows: the high-efficiency dynamic and static cone consists of a dynamic cone and a static cone, wherein the dynamic cone comprises a dynamic cone main body and a plurality of dynamic cone composite areas, and the dynamic cone composite areas are positioned on the conical surface of the dynamic cone; the static cone comprises a static cone main body and a plurality of static cone composite areas, and the static cone composite areas are positioned on the inner inclined surface of the static cone main body; a movable cone interval is formed between two adjacent movable cone composite regions, and a static cone interval is formed between two adjacent static cone composite regions; the movable cone composite region and the static cone composite region are both composed of ceramic particles and a metal matrix and are wavy; the movable cone interval and the static cone interval are both made of metal; the movable cone interval corresponds to the position of the static cone composite region, and the static cone interval corresponds to the position of the movable cone composite region.
Preferably, the dynamic cone composite region and the static cone composite region are both in a sine curve shape. The metal composite areas of the dynamic and static cones are distributed in a sine curve shape, so that materials can be efficiently drained into and stably arranged in the grooves.
Preferably, the ceramic particles have a particle size of 0.001mm to 5 mm.
Preferably, the dynamic cone main body and the static cone main body are both made of metal; the metal matrixes of the dynamic cone main body and the dynamic cone composite region can be the same or different metals, and the metal matrixes of the static cone main body and the static cone composite region can be the same or different metals.
Preferably, the dynamic cone main body and the dynamic cone composite region are connected in a casting mode.
Preferably, the width ratio between the moving cone interval and the static cone interval is 1-3: 1-5.
Preferably, the number of the dynamic cone composite areas and the number of the static cone composite areas are 4.
The utility model also discloses a crusher, which comprises the dynamic and static cone.
According to the utility model, the corrugated dynamic cone composite region and the corrugated static cone composite region are arranged, so that the residence time of the material in the composite region is increased, and the granularity of the product is ensured. Meanwhile, the grooves formed by the movable cone composite area and the movable cone are formed at intervals, and the grooves formed by the static cone composite area and the static cone are formed together to form an anti-slip board, so that material slipping can be reduced, materials can be gathered, and crushing efficiency is greatly improved.
Drawings
Fig. 1 is a schematic structural view of a high-efficiency dynamic and static cone provided by the utility model.
Wherein: 1-moving cone, 101-moving cone main body, 102-moving cone composite region, 2-static cone, 201-static cone main body, 202-static cone composite region, 3-moving cone interval and 4-static cone interval.
Detailed Description
For a better understanding of the nature of the present utility model, reference should be made to the following description of the utility model taken in conjunction with the accompanying drawings.
The utility model is suitable for crushing stones in industrial production, and particularly relates to a high-efficiency dynamic and static cone of a crusher, which is shown in fig. 1 and consists of a dynamic cone 1 and a static cone 2, wherein the dynamic cone 1 comprises a cone main body 101 and a plurality of dynamic cone composite areas 102, and the dynamic cone composite areas 102 are positioned on the conical surface of the dynamic cone 1; the static cone 2 comprises a static cone main body 201 and a plurality of static cone composite areas 202, wherein the static cone composite areas 202 are positioned on the inner inclined surface of the static cone main body 201; the dynamic cone composite region 102 and the static cone composite region 202 are both composed of ceramic particles and a metal matrix and are wavy; a movable cone interval 3 is formed between two adjacent movable cone composite regions 102, and a static cone interval 4 is formed between two adjacent static cone composite regions 202; the movable cone intervals 3 are arranged in one-to-one correspondence with the static cone composite areas 202, and the static cone intervals 4 are arranged in one-to-one correspondence with the movable cone composite areas 102. The width ratio between the movable cone interval 3 and the static cone interval 4 is 1-3: 1-5.
In some embodiments of the present utility model, both the dynamic cone composite zone 102 and the static cone composite zone 202 are sinusoidal. The metal composite areas of the dynamic and static cones are distributed in a sine curve shape, so that materials can be efficiently drained into and stably arranged in the grooves.
The ceramic particles are one or a mixture of any of oxides, carbides and nitrides; the granularity of the ceramic particles is 0.001 mm-5 mm.
The dynamic cone main body 101 and the static cone main body 201 are both made of metal; the metal substrates of the moving cone body 101 and the moving cone composite region 102 may be the same or different metals, and the metal substrates of the stationary cone body 201 and the stationary cone composite region 202 may be the same or different metals.
When the high-efficiency crusher dynamic and static cone is used, the ceramic-metal composite area has higher wear resistance than the metal-based plate hammer main body, so that the dynamic cone interval 3 and the static cone interval 4 are worn into grooves preferentially. At this time, the moving cone composite region 102 located on the conical surface of the moving cone 1, the stationary cone composite region 202 located on the inner inclined surface of the stationary cone 2 form ladder-shaped corrugated protrusions, and the materials are crushed by mutual extrusion of the moving cone composite region 102 and the corrugated protrusions on the stationary cone composite region 202. Because the dynamic cone composite region 102 and the static cone composite region 202 are in a corrugated shape, the residence time of materials in the dynamic cone composite region is increased, and the granularity of products is ensured. Meanwhile, the grooves formed by the movable cone composite region 102 and the movable cone interval 3 and the grooves formed by the static cone composite region 202 and the static cone interval 4 form an anti-slip board together, so that material slipping can be reduced, materials can be gathered, and crushing efficiency is greatly improved.
It should be noted that while the utility model has been described in terms of the above embodiments, there are many other embodiments of the utility model. Various modifications and variations of this utility model may be apparent to those skilled in the art without departing from the spirit and scope of this utility model, and it is intended to cover in the appended claims all such modifications and variations as fall within the true scope of this utility model.
Claims (8)
1. An efficient dynamic and static cone comprises a dynamic cone (1) and a static cone (2), and is characterized in that: the movable cone (1) comprises a movable cone main body (101) and a plurality of movable cone compound areas (102), and the movable cone compound areas (102) are positioned on the conical surface of the movable cone (1); the static cone (2) comprises a static cone main body (201) and a plurality of static cone composite areas (202), wherein the static cone composite areas (202) are positioned on the inner inclined surface of the static cone main body (201); a movable cone interval (3) is formed between two adjacent movable cone composite areas (102), and a static cone interval (4) is formed between two adjacent static cone composite areas (202); the dynamic cone composite region (102) and the static cone composite region (202) are both composed of ceramic particles and a metal matrix and are wavy; the movable cone interval (3) and the static cone interval (4) are both made of metal; the movable cone interval (3) corresponds to the position of the static cone composite region (202), and the static cone interval (4) corresponds to the position of the movable cone composite region (102).
2. The sound cone of claim 1, wherein: the dynamic cone composite region (102) and the static cone composite region (202) are both in a sine curve shape.
3. The sound cone of claim 1, wherein: the granularity of the ceramic particles is 0.001 mm-5 mm.
4. The sound cone of claim 1, wherein: the dynamic cone main body (101) and the static cone main body (201) are both made of metal; the metal matrixes of the dynamic cone main body (101) and the dynamic cone composite region (102) can be the same or different metals, and the metal matrixes of the static cone main body (201) and the static cone composite region (202) can be the same or different metals.
5. The sound cone of claim 1, wherein: the dynamic cone main body (101) and the dynamic cone composite region (102), and the static cone main body (201) and the static cone composite region (202) are connected in a casting mode.
6. The sound cone of claim 1, wherein: the width ratio between the movable cone interval (3) and the static cone interval (4) is 1-3: 1-5.
7. The sound cone of claim 1, wherein: the number of the dynamic cone composite areas (102) and the number of the static cone composite areas (202) are 4.
8. A crusher, characterized in that: comprising a sound cone according to any one of claims 1 to 7.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202320784399.1U CN219596716U (en) | 2023-04-11 | 2023-04-11 | Efficient sound awl and breaker |
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CN202320784399.1U CN219596716U (en) | 2023-04-11 | 2023-04-11 | Efficient sound awl and breaker |
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CN219596716U true CN219596716U (en) | 2023-08-29 |
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CN202320784399.1U Active CN219596716U (en) | 2023-04-11 | 2023-04-11 | Efficient sound awl and breaker |
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CN (1) | CN219596716U (en) |
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2023
- 2023-04-11 CN CN202320784399.1U patent/CN219596716U/en active Active
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