RU2778021C1 - Dual-purpose crusher and its operation method - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: invention relates to crushing devices. The crusher contains a material container assembly having a crushing head rigidly connected to the body of the material container, and a crushing sleeve connected with the possibility of rotation with the crushing head. The crushing head enters the crushing sleeve and defines with the crushing sleeve a material compartment for placing the material. The crusher also contains a connecting structure designed to be connected to an external power supply unit located at the upper end of the material container housing. The material container housing is made with the possibility of rotation and drive in rotation of the crushing head. At the same time, during manual crushing, the crushing sleeve moves relative to the crushing head so that the material is crushed between the crushing head and the crushing sleeve. During automatic crushing, the body of the material container is connected to the external power unit by means of a connecting structure and is rotated by the external power unit so that the crushing head is rotated.

EFFECT: crusher provides the possibility of manual and automatic grinding.

9 cl, 17 dwg

Description

[01] The present application is based on Chinese Patent Application No. 201910161100.5, filed March 4, 2019, which claims priority. The full disclosure of this application is incorporated herein by reference in its entirety.

[02] TECHNICAL FIELD

[03] The present application relates to a crusher and, in particular, to a dual-use crusher and its method of operation.

[04] PRIOR ART

[05] The crusher and pulverizer used in real life, whether it is a steel crusher or a ceramic crusher, usually make the material finer and finer by crushing and compressing the material between the movable crushing plate and the fixed crushing plate, so that the production efficiency of the crusher and the grinding fineness material depends on the degree of fit between the movable crushing plate and the fixed crushing plate.

[06] Existing crushers are generally operated manually or automatically. Manual grinders can produce finer powder and may allow for controlled grinding speed, but have poor operating efficiency, while automatic grinders can improve operating efficiency but are costly. At present, there is no crusher that can realize both manual grinding and automatic grinding modes, therefore, it cannot meet the different requirements of users at the same time.

[07] Therefore, it is necessary to develop a crusher that can realize manual crushing and can also be applied with a driving part to obtain an automatic crusher having manual and automatic modes to meet different requirements of users.

[08] SUMMARY OF THE INVENTION

[09] The purpose of the present application is to provide a dual-use crusher and a method for operating it to overcome the shortcomings of the prior art.

[010] In order to achieve the above object, the present application proposes a dual purpose crusher that includes a material container assembly. The material container assembly comprises a crushing head rigidly connected to the material container body and a crushing sleeve rotatably connected to the crushing head. The crushing head is inserted into the crushing sleeve, wherein the crushing head and the crushing sleeve define a material compartment between them to accommodate the material. At the upper end of the material container body, there is a connection structure configured to be connected to an external power unit. When manual grinding is needed, the material container body rotates and drives the crushing head, the crushing sleeve moves relative to the crushing head, so that the material between the crushing head and the crushing sleeve is pulverized. When automatic crushing is needed, the material container body is connected to the external feed assembly through a connecting structure, and driven by the external feed assembly, so that the crushing head is driven, the crushing sleeve is moved relative to the crushing head, so that the material between the crushing head and the crushing sleeve is crushed. into powder.

[011] In addition, the connecting structure includes a connecting column that contains a protruding stem. At the upper end of the protruding rod there is a cone-shaped platform, while the diameter of the lower surface of the cone-shaped platform is greater than the diameter of the transverse section of the protruding rod.

[012] In addition, the connecting structure further has a first groove, while the connecting column is located in the first groove.

[013] In addition, a transfer frame is disposed in the material container body, and on the transfer frame there is a connecting rod connected to the crushing head.

[014] In addition, the crushing head includes a frustoconical body and a number of crushing plates, with a number of crushing plates spaced around the surface of the lower end of the frustoconical body. The truncated cone body has a hole for inserting a connecting rod. The surface of the lower end of the body in the form of a truncated cone is concave inward to form a control groove, and the control spring is inserted into the control groove.

[015] In addition, the material container assembly further comprises a fixing frame with mounting columns located thereon, while the crushing sleeve has mounting grooves into which the mounting columns are inserted. Mounting columns are included in the mounting grooves.

[016] In addition, the connection structure includes an interlock switch that includes two inverted clamp sections for securing the external power assembly.

[017] In addition, a connection frame is located in the material container body, wherein the connection frame is connected to the crushing head through the rotating shaft of the crushing head, a second through groove is located in the connection frame, and the interlock switch is located in the second through groove.

[018] In addition, the lower end of the rotary shaft of the crushing head is connected to an adjusting structure for adjusting the size of the gap between the crushing head and the crushing sleeve, while the regulating structure includes an adjusting spring fitted on the rotating shaft of the crushing head, and a regulator connected to the rotating shaft of the crushing head. heads. The control spring is located between the crushing head and the connecting frame, and the adjuster is located below the crushing head.

[019] This application further provides a method for operating a dual purpose crusher, including:

[020] rotating the body of the material container when manual pulverization is needed, thereby allowing the crushing head to rotate and move the crushing sleeve and the crushing head relative to each other so that the material therebetween is crushed and compressed into a powder;

[021] Connecting an external power unit to the connection structure when automatic grinding is needed, wherein the external power unit rotates the material container body to drive the crushing head and move the crushing sleeve and the crushing head relative to each other so that the material between them crushed and pressed into powder.

[022] The present application has the following advantages over the prior art: By providing a connection structure on the material container body, an external power node can be connected with the connection structure. The material container assembly can be used by itself for manual shredding, or it can be connected to an external power assembly to become an automatic crusher. The crushing head and the crushing sleeve are moved relative to each other by the rotation of the material container body. Both manual and automatic modes can be implemented to meet different user requirements.

[023] The present application is further described below in conjunction with the accompanying drawings and specific embodiments.

[024] BRIEF DESCRIPTION OF THE DRAWINGS

[025] In order to more clearly explain the technical solutions of the embodiments of the present application, the drawings mentioned in the description of the embodiments are briefly described. It is obvious that the graphics described below are some embodiments of the present application, and specialists in the art can obtain other graphics based on these graphics without creative work.

[026] In FIG. 1 is a structural perspective view of a dual purpose crusher of a specific embodiment of the present application;

[027] In FIG. 2 is an exploded structural view of a dual purpose crusher proposed in a specific embodiment of the present application;

[028] In FIG. 3 is a structural cross-sectional view of a dual purpose crusher proposed in a specific embodiment of the present application;

[029] In FIG. 4 is a structural perspective view of a crushing head provided in a specific embodiment of the present application;

[030] In FIG. 5 is a structural perspective view of a crushing sleeve provided in a specific embodiment of the present application;

[031] In FIG. 6 is a structural perspective view of a transmission frame proposed in a specific embodiment of the present application;

[032] In FIG. 7 is a structural perspective view of a fixing frame provided in a specific embodiment of the present application;

[033] In FIG. 8 is a structural perspective view of a material container body of a particular embodiment of the present application;

[034] In FIG. 9 is a structural perspective view of a dual purpose crusher of another specific embodiment of the present application;

[035] In FIG. 10 is an expanded structural view of a dual purpose crusher of another specific embodiment of the present application;

[036] In FIG. 11 is a structural cross-sectional view of a dual purpose crusher of another specific embodiment of the present application;

[037] In FIG. 12 is a structural perspective view of a connection frame provided in another specific embodiment of the present application;

[038] In FIG. 13 is a structural perspective view of a crushing head provided in another specific embodiment of the present application;

[039] In FIG. 14 is a structural perspective view of a crushing sleeve provided in another specific embodiment of the present application;

[040] In FIG. 15 is a structural perspective view of a connecting base provided in another particular embodiment of the present application;

[041] In FIG. 16 is a structural perspective view of a locking base provided in another specific embodiment of the present application; and

[042] In FIG. 17 is a structural perspective view of an interlock switch provided in another specific embodiment of the present application.

[043] DETAILED DESCRIPTION OF EMBODIMENTS

[044] The technical solutions of the embodiments of the present application will be clearly and fully described in conjunction with the accompanying drawings in the embodiments of the present application. Obviously, the described embodiments are only some embodiments of the present application, and not all. Based on the embodiments of the present application, all other embodiments obtained by those skilled in the art without creative work fall within the protection scope of this application.

[045] It should be understood that when used in the description and the accompanying claims, the terms "comprising" and "comprising" indicate the presence of the described features, integer values, steps, operations, elements and / or components, but do not exclude the presence or addition of one or more than other signs, integer values, steps, operations, elements, components and / or their combination.

[046] It should also be understood that the terms used in the description of the present application are only intended to describe specific embodiments and are not intended to limit the application. In the context of the description and the appended claims of the present application, unless the context clearly indicates otherwise, it is understood that the singular forms include the plural forms.

[047] Additionally, it should be understood that the term "and/or" as used in the description and appended claims of the present application refers to any and all possible combinations of one or more related listed elements and includes these combinations.

[048] As shown in the embodiments of FIG. 1 to 17, the dual-purpose crusher of the present embodiment is designed for indoor and outdoor dual-purpose crushing, including manual crushing and automatic crushing, thus meeting different user requirements.

[049] The dual purpose crusher includes a material container assembly. The material container assembly comprises a crushing head 12, 27 rigidly connected to the material container body 10, 20 and a crushing sleeve 15, 26 rotatably connected to the crushing head 12, 27. The crushing head 12, 27 is inserted into the crushing sleeve 15 , 26, wherein the crushing head 12, 27 and the crushing sleeve 15, 26 define a material compartment between them to accommodate the material. At the upper end of the body 10, 20 of the material container is a connecting structure, configured to be connected to an external power unit. When manual grinding is required, the material container body 10, 20 rotates and drives the crushing head 12, 27, the crushing arm 15, 26 moves relative to the crushing head 12, 27 so that the material between the crushing head 12, 27 and the crushing arm 15, 26 is ground into powder. When automatic grinding is required, the material container body 10, 20 is connected to the external feed assembly by a connecting structure, and is driven by the external feed assembly so that the crushing head 12, 27 is driven, the crushing sleeve 15, 26 is moved relative to the crushing head so that that the material between the crushing head 12, 27 and the crushing sleeve 15, 26 is pulverized.

[050] By arranging the connecting structure on the manual shredding structure, an external power unit can be connected. An external power node provides power for switching to automatic grinding, which is convenient for the transition and has good practical feasibility.

[051] In FIG. 1-8, an embodiment of a dual purpose crusher is provided. In this embodiment, the connecting structure includes a connecting column, and the connecting column includes a protruding rod 102. At the upper end of the protruding rod is a cone-shaped platform 103, and the diameter of the bottom surface of the conical platform 103 is larger than the cross-sectional diameter of the protruding rod 102. The protruding rod 102 and the conical platform 103 form a stepped shape. The external power supply may be a power supply with a blocking switch. The power assembly can start by attaching an interlock switch and a connecting column, thus supplying power to the crusher. In addition, by providing a connecting column and forming a stepped shape between the protruding stem 102 and the cone-shaped platform 103, the interlock switch can be attached to the connecting column.

[052] When the connecting column is inserted into the interlock switch and comes into contact with the central part of the interlock switch for the first time, a pair of inverted clamp sections of the interlock switch are engaged with the connecting column so that the crusher becomes one with the external power unit to form a full-fledged automatic crusher . When the connecting column is advanced further into the interlock switch and comes into contact with the central part of the interlock switch a second time, the pair of inverted clamp sections of the interlock switch are released and the crusher is separated from the external feed assembly, thus the external feed assembly can be used with other crushers containing different materials, and the same steps are carried out to obtain another automatic crusher. Only one step is required to connect to an external power node, which is a simple and effective solution, and the crusher not connected to an external power node can be used as a hand crusher.

[053] In addition, in FIG. 1 and 8, the connection structure further has a first groove 101, with the connection column located in the first groove 101. The external power assembly intended to be inserted into the first groove 101 may be spaced to form a stable connection structure with connections both in the center and along the edges, and the direction of the external power node.

[054] In FIG. 6, a transfer frame 11 is located in the material container body 10, and on the transfer frame 11 there is a connecting rod 111 connected to the crushing head 12. The transfer frame 11 is driven by rotation of the material container body 10. Since the crushing head 12 is connected to the connecting rod 111, the crushing head 12 rotates with the rotation of the transmission frame 11.

[055] Preferably, the outer edge of the transfer frame 11 has a projecting ring 112, the above material container body 10 has a locking groove, and the projecting ring 112 is inserted into the locking groove so that the transfer frame 11 is connected to the material container body 10 so as to bring into rotation of the transmission frame 11 by rotating the material container body 10 .

[056] Preferably, the lower end of the above connecting rod 11 is in threaded connection with the adjusting structure for adjusting the size of the gap between the crushing head 12 and the crushing sleeve 15. the control spring 141 enters the crushing head.

[057] When the control rod 14 rotates and moves upward, the control spring 141 is compressed by the control rod 14, causing the crushing head to move upward, so that the gap between the crushing head and the crushing sleeve becomes smaller and the ground powder is finer. When the control rod 14 rotates and moves down, the pressure force exerted on the control spring 141 by the control rod 14 decreases, the crushing head moves down, and the gap between the crushing head and the crushing arm becomes larger, so the crushed powder becomes coarser.

[058] In addition, as shown in FIG. 4, the crushing head 12 includes a frustoconical body 121 and a number of crushing plates 122, with a number of crushing plates 122 spaced around the surface of the lower end of the frustoconical body 121. The frustoconical body 121 has an opening 123 for inserting the connecting rod 111. The surface of the lower end of the frustoconical body 121 is concave inwards to form a control slot 124, and the control spring 141 fits into the control slot 124. Through the combined action of the crushing plates 122 and crushing sleeve 15 is crushing and compressing the material into powder.

[059] In the present embodiment, the above connecting rod 111 has a rectangular shape. In other embodiments, the aforementioned connecting rod 111 may also have other shapes, such as a pentagonal shape. The shape of the hole 123 matches the shape of the connecting rod 111 to facilitate installation.

[060] In addition, as shown in FIG. 5 and 7, the above material container assembly further comprises a fixing frame 13, on the fixing frame 13 there are setting columns 131, and on the crushing arm 15 there are setting grooves 151 into which the setting columns 131 are inserted. The fixing frame 13 is connected to the control structure.

[061] Between the crushing sleeve 15, the fixing frame 13 and the transfer frame 11, a closed space is formed when the material is fed, thereby preventing other particles from entering, so as to guarantee the taste of the material.

[062] In FIG. 9-17 in another embodiment of a dual purpose crusher as shown in FIG. 17, the connection structure includes an interlock switch 31 which includes two inverted clamp sections for securing the external power unit. The external power unit may have a connecting column designed to be fixed with inverted clamp sections. The structure of the connecting column corresponds to the structure of the connecting column in the previous embodiment.

[063] In the embodiment of FIG. 11 and 12, a connecting frame is disposed in the material container body 20, and the connecting frame is connected to the crushing head 27 via the rotating shaft 23 of the crushing head. There is a second slot 213 in the connecting frame. The external power unit drives the connecting structure, and the connecting structure drives the connecting frame, and the crushing head 27 is driven by the connecting frame through the rotating shaft 23 of the crushing head, thereby realizing automatic grinding. .

[064] In the embodiment of FIG. 10 and 12, the second through groove 212 is located in the connecting frame, and the interlock switch 31 is located in the second through groove 212.

[065] The control structure and the material container assembly are connected by the interlock switch 31 so that the control structure causes the material container assembly to perform pulverization.

[066] In particular, in FIG. 12, the above connecting frame includes a first connecting frame 21 and a second connecting frame 22. The material container body 20 has a fastening hole with a fixing ring 201 therein, and the upper end of the first connecting frame 21 has a fixing edge that is connected to the fixing ring 201. The above the second groove 213 is on the first connection frame 21, the second through groove 212 passes through the first connection frame 21, while the first connection frame 21 is connected to the second connection frame 22. The protruding column 223 extends down from the lower end of the second connection frame 22, while in protruding column 223 is a hole for the rotary shaft, the rotary shaft 23 of the crushing head enters the hole for the rotary shaft. Therefore, the rotation of the first connecting frame 21 rotates the second connecting frame 22, and the rotation of the second connecting frame 22 rotates the crushing head rotating shaft 23, which in turn drives the crushing head 27, thereby performing automatic grinding. Compact structure and stable transmission process can be ensured.

[067] In addition, in particular, the upper end of the first connecting frame 21 further has a guide groove, which is located adjacent to the first groove 101. The external power assembly and the connecting structure are pressed against each other and aligned with each other when the material container body is attached and external power supply. In addition, the guide groove can guide the crushing head 27 so that the material container body 20 can rotate without moving up and down, and the crushing head 27 rotates clockwise when the material container body 20 rotates clockwise.

[068] In addition, the lower end of the first connecting frame 21 also has a plug 214 and a hook 211, and the second connecting frame 22 has a socket 221 and a groove for the hook 222. The plug 214 is inserted into the socket 221, and the hook 211 is located in the groove for the hook 222 so as to connect the first connecting frame 21 and the second connecting frame 22.

[069] In the embodiment of FIG. 10, the lower end of the crushing head rotating shaft 23 is connected to an adjusting structure for adjusting the size of the gap between the crushing head 27 and the crushing sleeve 26, while the regulating structure includes an adjusting spring 24 fitted on the crushing head rotating shaft 23, and a regulator 28 connected to the rotating shaft. 23 crushing heads. The control spring 24 is located between the crushing head 27 and the connection frame, and the regulator 28 is located below the crushing head 27. In particular, the control spring 24 is located between the crushing head 27 and the second connection frame 22.

[070] The rotary shaft 23 of the crushing head is threaded so as to fix the regulator 28 after rotation.

[071] In the embodiment of FIG. 13, the crushing head 27 includes a frustoconical body 271 which has a pointed tooth 272.

[072] As the adjuster 28 rotates and moves upward, the adjusting spring 24 is compressed by the adjuster 28, causing the crushing head 27 to move upward, so that the gap between the crushing head 27 and the crushing sleeve 26 becomes smaller and the ground powder becomes finer. When the adjuster 28 rotates and moves down, the pressure force exerted on the adjusting spring by the adjuster 28 decreases, the crushing head 27 moves down, and the gap between the crushing head 27 and the crushing sleeve 26 becomes larger, thus the crushed powder is coarser.

[073] In the embodiment of FIG. 15 and 16, the lower end of the material container body 20 is connected to a connecting base 25 having a first through hole 253. The crushing head 27 is placed in the first through hole 253, and the upper end of the crushing sleeve 26 is inserted into the first through hole 253. The lower end of the connecting base 25 is connected to the fixing base 29 having the first through groove, and on both sides of the first through groove there are the first fixing blocks 291. The lower edge of the crushing sleeve 26 has cutouts 261 into which the first fixing blocks 291 are inserted.

[074] In addition, the crushing sleeve 26 has a crushing groove, while the crushing head 27 is located in the crushing groove of the crushing sleeve 26.

[075] In particular, the inner side wall of the material container body 20 has second locking blocks, and the connecting base 25 has connecting grooves 251. The second fixing blocks engage with the connecting grooves 251 to connect the material container body 20 to the connecting base 25. The crushing sleeve 26, the crushing head 27 and the material container body 20 form an independent structure by means of the connecting base 25.

[076] In addition, in order to facilitate assembly of the material container body 20 and the connecting base 25, the material container body 20 has limit rods, and the connection base has limit holes 254 into which the limit rods are inserted for installation.

[077] In the embodiment of FIG. 15 on the outer edge of the connecting base 25 is a circular groove 252, and inside the locking base 29 are the protrusions 292, while the protrusions 292 engage with the circular groove 252, thus connecting the connecting base 25 with the locking base 29. When the cutouts 261 are aligned and the first fixing blocks 291, the crushing sleeve 26 can remain stationary while the crushing head 27 rotates clockwise, so that the material can be crushed into a powder having the same size as the gap between the crushing head 27 and the crushing sleeve 26, through a pointed tooth 272 and spill out of the gap, completing the grinding process.

[078] In particular, in the first through groove is a restrictive ring 293, while the restrictive ring 293 is located below the first fixing blocks 291 to accommodate the crushing sleeve 26 during attachment.

[079] In the above two embodiments, the connection column is located on the crusher and the interlock switch is located on the external power node, or the interlock switch is located on the crusher and the connection column is located on the external power node. Interlock switches and connecting columns have the same design in the two embodiments.

[080] By providing a connecting structure on the material container body 10, 20 for connecting with an external power unit, the above dual-purpose crusher can realize manual crushing using only the material container body 10, 20, or obtain an automatic crusher by combining the container body for material and external power supply. By rotating the material container body 10, 20, the crushing head 12, 27 and the crushing arm 15, 26 move relative to each other so that manual and automatic modes can be implemented to meet different user requirements.

[081] In addition, the present embodiments also provide a method for operating a dual-purpose crusher, which includes:

[082] in case manual grinding is required, rotating the material container body 10, 20 so as to rotate the crushing head 12, 27. The crushing sleeve 15, 26 and the crushing head 12, 27 move relative to each other so that the material between the crushing head 12, 27 head 12, 27 and crushing sleeve 15, 26 is crushed and pressed into powder;

[083] in case of need for automatic grinding, connecting the external power unit to the connecting structure. The external power assembly rotates the material container body 10, 20 to drive the crushing head 12, 27. The crushing sleeve 15, 26 and the crushing head 12, 27 move relative to each other so that the material between them is crushed and pressed into powder.

[084] It should be noted that those skilled in the art can clearly understand that the specific process for implementing the method of operating the above dual-use crusher may refer to the corresponding description in the above embodiment of the dual-use crusher and will not be repeated herein for the sake of brevity.

[085] The technical content of this application is further explained by the above examples only to facilitate understanding by readers, but the implementation of the present application is not limited to them. Any technical expansion or recreation made in accordance with this application is subject to the scope of protection of this application. The scope of protection of the present application is defined in accordance with the claims.

Claims (9)

1. A crusher, characterized in that it comprises a material container assembly having a crushing head rigidly connected to the material container body, and a crushing sleeve rotatably connected to the crushing head, the crushing head entering the crushing sleeve, the crushing head and the crushing sleeve defines between them a material compartment for material placement, a connecting structure configured to be connected to an external power unit located at the upper end of the material container body, while for manual crushing, the material container body rotates and drives the crushing head , the crushing sleeve moves relative to the crushing head so that the material between the crushing head and the crushing sleeve is crushed into powder, and for automatic crushing, the material container body is connected to the external power unit through the connecting structure and driven by the external by means of a feed unit so that the crushing head is rotated, while the crushing sleeve is moved relative to the crushing head so that the material between the crushing head and the crushing sleeve is crushed into powder. 2. Crusher according to claim. 1, characterized in that the connecting structure further comprises a connecting column, which contains a protruding rod, and the diameter of the lower surface of the cone-shaped platform is greater than the diameter of the cross section of the protruding rod. 3. Crusher according to claim. 2, characterized in that the connecting structure additionally contains the first groove, and the connecting column is located in the first groove. 4. Crusher according to any one of paragraphs. 1–3, characterized in that a transfer frame is located in the body of the material container, while on the transfer frame there is a connecting rod connected to the crushing head. 5. The crusher according to claim. 4, characterized in that the crushing head contains a body in the form of a truncated cone and a number of crushing plates, and a number of crushing plates are located at intervals around the surface of the lower end of the body in the form of a truncated cone, the body in the form of a truncated cone has a hole for inserting the connecting rod, the surface of the lower end of the body in the form of a truncated cone is concave inward to form an adjusting groove, and the adjusting spring enters the adjusting groove. 6. The crusher according to claim 5, characterized in that the material container assembly additionally comprises a fixing frame with mounting columns located on it, there are mounting grooves on the crushing sleeve into which the mounting columns are inserted, while the mounting columns enter the mounting grooves. 7. Crusher according to claim. 1, characterized in that the connecting structure contains a blocking switch, which contains two inverted clamping sections for fixing the external power unit. 8. The crusher according to claim 7, characterized in that a connecting frame is located in the body of the material container, while the connecting frame is connected to the crushing head by means of a rotating shaft of the crushing head, the second through groove is located in the connecting frame, and the blocking switch is located in the second through groove. 9. The crusher according to claim 8, characterized in that the lower end of the rotating shaft of the crushing head is connected to the control structure for adjusting the size of the gap between the crushing head and the crushing sleeve, while the control structure contains a control spring put on the rotating shaft of the crushing head, and the regulator , connected to the rotating shaft of the crushing head, the control spring is located between the crushing head and the connecting frame, and the adjuster is located below the crushing head.

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