CN113276468A

CN113276468A - Reciprocating motion extrusion formula material setting device

Info

Publication number: CN113276468A
Application number: CN202110632734.1A
Authority: CN
Inventors: 刘金玲
Original assignee: Individual
Current assignee: Cixi Gongli Magnetic Industrial Co ltd
Priority date: 2021-06-07
Filing date: 2021-06-07
Publication date: 2021-08-20
Anticipated expiration: 2041-06-07
Also published as: CN113276468B

Abstract

The invention discloses a reciprocating extrusion type material setting device which comprises a main hollow shell. The invention utilizes a reciprocating type driving source to drive the curve reciprocating mechanism to move up and down, in the moving process of the curve reciprocating mechanism, the friction driven type rotating mechanism can realize the rotary driving of the friction driven type rotating mechanism on the premise of static friction, and the spiral feeding blade is driven to rotate under the linkage rotary transmission of parts, so that materials can be input and operated controllably under the action of the same power source.

Description

Reciprocating motion extrusion formula material setting device

Technical Field

The invention relates to the technical field of material setting, in particular to a reciprocating extrusion type material setting device.

Background

At present, some powdered materials need utilize setting device, just can be with material compression moulding, and current setting device needs two driving sources, one when the design: need drive reciprocating rod reciprocating, its two, need drive the equipment of filling the material to two kinds of equipment need a monitoring device to control in order to control the emission degree of material, and the process is loaded down with trivial details, and need cooperate equipment each other than many, the error appears easily.

Disclosure of Invention

The invention aims to provide a reciprocating extrusion type material setting device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a reciprocating motion extrusion type material shaping device comprises a main hollow shell, wherein a limiting plate mounting groove is arranged at the center of the bottom end of the main hollow shell, a main limiting plate capable of being taken out is mounted in the limiting plate mounting groove, a reciprocating motion compression space is arranged at the top end of the limiting plate mounting groove, two opposite side faces of the reciprocating motion compression space are respectively provided with a material storage space, the top end of one side of each of the two material storage spaces is provided with a feeding hole communicated with the outside, the bottom ends of the two material storage spaces are respectively provided with a funnel-type material leaking groove, the bottom ends of the two funnel-type material leaking grooves are respectively provided with a transverse feeding space, the opposite ends of the two feeding spaces are respectively communicated with two sides of the reciprocating motion compression space, a discharging port for communicating the feeding space with the side faces of the reciprocating motion compression space is formed in the main hollow shell, two sides of the main hollow shell are respectively inserted into, a main belt wheel is arranged at one end of each main rotating shaft positioned outside, a component mounting space is arranged above the reciprocating motion compression space, a top component telescopic hole is formed in the top end of the component mounting space, two sides of each main hollow shell are respectively provided with an auxiliary rotating shaft extending into the component mounting space through bearings, an auxiliary belt wheel is arranged at one end of each auxiliary rotating shaft positioned outside, the main belt wheel and the auxiliary belt wheel on each corresponding vertical line are connected through a belt, each main rotating shaft is provided with a spiral feeding blade on a shaft body positioned inside the feeding space, the longitudinal center of each main hollow shell penetrates through the top component telescopic hole and the middle component telescopic hole from top to bottom to form a curve reciprocating mechanism capable of vertically reciprocating motion, and the curve reciprocating mechanism is arranged inside the top component telescopic hole, the component mounting space, the middle component telescopic hole and the reciprocating motion compression space, the top end of the curve reciprocating mechanism is provided with a main connecting plate, one end of the curve reciprocating mechanism, which is positioned in the reciprocating motion compression space, is provided with a punch, and one ends of the two pairs of rotating shafts, which are positioned in the component mounting space, are respectively provided with a friction driven type rotating mechanism.

Furthermore, the spiral direction of the two spiral feeding blades is set according to the feeding direction, namely, the feeding direction formed by the rotation of the spiral feeding blades is towards the reciprocating motion compression space on the premise that the spiral feeding blades are driven by the belt to rotate.

Further, the curve reciprocating mechanism comprises a rod body for the curve reciprocating mechanism, a left semi-cylindrical slide rail structure for the curve reciprocating mechanism and a right semi-cylindrical slide rail structure for the curve reciprocating mechanism, the rod body for the curve reciprocating mechanism is respectively provided with the left semi-cylindrical slide rail structure for the curve reciprocating mechanism and the right semi-cylindrical slide rail structure for the curve reciprocating mechanism on opposite two sides, and the left semi-cylindrical slide rail structure for the curve reciprocating mechanism and the right semi-cylindrical slide rail structure for the curve reciprocating mechanism are structures with consistent and symmetrical structural appearances.

Further, the friction driven type rotating mechanism comprises a rotating sleeve for the friction driven type rotating mechanism, an annular chute for the friction driven type rotating mechanism, a part mounting hole for the friction driven type rotating mechanism, a unidirectional rotating flywheel for the friction driven type rotating mechanism, a lantern ring for the friction driven type rotating mechanism and a shaft body mounting hole for the friction driven type rotating mechanism, wherein the annular chute for the friction driven type rotating mechanism is arranged inside the circumferential side surface of the rotating sleeve for the friction driven type rotating mechanism, the part mounting hole for the friction driven type rotating mechanism is arranged in the center inside the rotating sleeve for the friction driven type rotating mechanism, the unidirectional rotating flywheel for the friction driven type rotating mechanism is sleeved on the inner side of the part mounting hole for the friction driven type rotating mechanism, the lantern ring for the friction driven type rotating mechanism is arranged in the center of the unidirectional rotating flywheel for the friction driven type rotating mechanism, and a shaft body mounting hole for the friction driven type rotating mechanism is formed in the center of the lantern ring for the friction driven type rotating mechanism.

Further, the one-way rotation flywheel for a friction driven rotation mechanism has a one-way rotation structure, and when the flywheel is rotated in the forward direction, the rotation sleeve for a friction driven rotation mechanism can be rotated along with the collar for a friction driven rotation mechanism, and when the flywheel is not rotated in the forward direction, the rotation sleeve for a friction driven rotation mechanism can be rotated relatively.

Furthermore, the friction driven type rotating mechanism is provided with a shaft body of the auxiliary rotating shaft inside the shaft body mounting hole, and the annular sliding groove for the friction driven type rotating mechanism is abutted to the surfaces of the left semi-cylindrical sliding rail structure for the curve reciprocating mechanism and the right semi-cylindrical sliding rail structure for the curve reciprocating mechanism.

Compared with the prior art, the invention has the beneficial effects that: the invention utilizes a reciprocating type driving source to drive the curve reciprocating mechanism to move up and down, in the moving process of the curve reciprocating mechanism, the friction driven type rotating mechanism can realize the rotary driving of the friction driven type rotating mechanism on the premise of static friction, and the spiral feeding blade is driven to rotate under the linkage rotary transmission of parts, so that materials can be input and operated controllably under the action of the same power source.

Drawings

FIG. 1 is a schematic view of a full-section structure of a reciprocating extrusion type material setting device of the present invention;

FIG. 2 is a schematic structural view of a curved reciprocating mechanism in the reciprocating extrusion type material setting device of the invention;

FIG. 3 is a schematic structural view of a friction driven type rotating mechanism in the reciprocating extrusion type material setting device of the present invention;

in the figure: 1, a main hollow shell, 2, a limit plate mounting groove, 3, a main limit plate, 4, a reciprocating motion compression space, 5, a discharge port, 6, a feeding space, 7, a main rotating shaft, 8, a main belt pulley, 9, a punch, 10, a spiral feeding blade, 11, a funnel type material leaking groove, 12, a material storage space, 13, a feeding hole, 14, a middle part telescopic hole, 15, a curve reciprocating mechanism, 151, a rod body for the curve reciprocating mechanism, 152, a left semi-cylindrical slide rail structure for the curve reciprocating mechanism, 153, a right semi-cylindrical slide rail structure for the curve reciprocating mechanism, 16, a top part telescopic hole, 17, a main connecting plate, 18, a part mounting space, 19, an auxiliary belt pulley, 20, an auxiliary rotating shaft, 21, a friction driven rotating mechanism, 211, a rotating sleeve for the friction driven rotating mechanism, 212, an annular slide groove for the friction driven rotating mechanism, 213 and a part mounting hole for the friction driven rotating mechanism, 214, a one-way rotation flywheel for a friction driven type rotation mechanism 215, a collar for a friction driven type rotation mechanism 216, a shaft body mounting hole for a friction driven type rotation mechanism 22, and a belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention: comprises a main hollow shell 1, a limiting plate mounting groove 2 is arranged at the center of the bottom end of the main hollow shell 1, a main limiting plate 3 which can be taken out is arranged in the limiting plate mounting groove 2, a reciprocating motion compression space 4 is arranged at the top end of the limiting plate mounting groove 2, two opposite side surfaces of the reciprocating motion compression space 4 are respectively provided with a material storage space 12, the top end of one side of each material storage space 12 is provided with a feeding hole 13 communicated with the outside, the bottom ends of the two material storage spaces 12 are respectively provided with a funnel type material leaking groove 11, the bottom ends of the two funnel type material leaking grooves 11 are respectively provided with a transverse feeding space 6, the opposite ends of the two feeding spaces 6 are respectively communicated with two sides of the reciprocating motion compression space 4, a discharging hole 5 used for communicating the feeding space 6 with the side surfaces of the reciprocating motion compression space 4 is arranged in the main hollow shell 1, two sides of the main hollow shell 1 are respectively and deeply extend into the main rotating shaft 7 in the feeding space 6 through bearings, a main belt pulley 8 is arranged at one end of each main rotating shaft 7 positioned outside, a component mounting space 18 is arranged above the reciprocating motion compression space 4, a top component telescopic hole 16 is formed in the top end of the component mounting space 18, two sides of each main hollow shell 1 are respectively provided with an auxiliary rotating shaft 20 extending into the component mounting space 18 through bearings, one end of each auxiliary rotating shaft 20 positioned outside is respectively provided with an auxiliary belt pulley 19, each main belt pulley 8 and each auxiliary belt pulley 19 on the corresponding vertical line are connected through a belt 22, each main rotating shaft 7 is provided with a spiral feeding blade 10 on a shaft body positioned inside the feeding space 6, the longitudinal center of each main hollow shell 1 penetrates through the top component telescopic hole 16 and the middle component telescopic hole 14 from top to bottom to form the top component telescopic hole 16 and the middle component telescopic hole 14 respectively, and the top component telescopic hole 16, the component mounting space 18, the middle component telescopic hole 14 and a curve capable of reciprocating motion can be arranged inside the reciprocating motion compression space 4 in a vertical reciprocating motion mode A reciprocating mechanism 15, a main connecting plate 17 is arranged at the top end of the curve reciprocating mechanism 15, a punch 9 is arranged at one end of the curve reciprocating mechanism 15 positioned in the reciprocating motion compression space 4, and two friction driven type rotating mechanisms 21 are respectively arranged at one ends of two auxiliary rotating shafts 20 positioned in the component mounting space 18.

The spiral direction of the two spiral feeding blades 10 is set according to the feeding direction, i.e. the feeding direction formed by the rotation of the spiral feeding blades 10 faces the reciprocating motion compression space 4 on the premise that the spiral feeding blades 10 are driven by the belt 22 to rotate.

Referring to fig. 2, the curve reciprocating mechanism 15 includes a rod 151 for curve reciprocating mechanism, a left semi-cylindrical slide rail structure 152 for curve reciprocating mechanism, and a right semi-cylindrical slide rail structure 153 for curve reciprocating mechanism, the rod 151 for curve reciprocating mechanism is provided with the left semi-cylindrical slide rail structure 152 for curve reciprocating mechanism and the right semi-cylindrical slide rail structure 153 for curve reciprocating mechanism on two opposite sides, respectively, and the left semi-cylindrical slide rail structure 152 for curve reciprocating mechanism and the right semi-cylindrical slide rail structure 153 for curve reciprocating mechanism are structures with identical and symmetrical structural shapes.

Referring to fig. 3, the friction driven type rotation mechanism 21 includes a friction driven type rotation mechanism rotation sleeve 211, a friction driven type rotation mechanism annular chute 212, a friction driven type rotation mechanism member mounting hole 213, a friction driven type rotation mechanism unidirectional rotation flywheel 214, a friction driven type rotation mechanism collar 215, and a friction driven type rotation mechanism shaft body mounting hole 216, the friction driven type rotation mechanism annular chute 212 is provided inside the circumferential side surface of the friction driven type rotation mechanism rotation sleeve 211, the friction driven type rotation mechanism member mounting hole 213 is provided in the center inside the friction driven type rotation mechanism rotation sleeve 211, a friction driven type rotation mechanism unidirectional rotation flywheel 214 is fitted inside the friction driven type rotation mechanism member mounting hole 213, the friction driven type rotation mechanism unidirectional rotation flywheel 214 is provided in the center thereof, a shaft body mounting hole 216 for a friction driven rotary mechanism is provided in the center of the collar 215 for a friction driven rotary mechanism.

The unidirectional rotation flywheel 214 for a friction driven type rotation mechanism has a unidirectional rotation structure, and can rotate the rotation sleeve 211 for a friction driven type rotation mechanism along with the collar 215 for a friction driven type rotation mechanism when rotating in the forward direction, and can rotate relatively when not rotating.

The shaft body of the auxiliary rotating shaft 20 is installed inside the shaft body installation hole 216 for the friction driven type rotating mechanism, and the annular chute 212 for the friction driven type rotating mechanism abuts against the surfaces of the left half-cylindrical slide rail structure 152 for the curve reciprocating mechanism and the right half-cylindrical slide rail structure 153 for the curve reciprocating mechanism.

The specific use mode is as follows: in the working process of the invention, a main connecting plate 17 is fixedly connected with the end part of a telescopic rod of a reciprocating telescopic cylinder, then material powder to be shaped is put into the two material storage spaces 12, when a curve reciprocating mechanism 15 is driven to move up and down, in the moving process of the curve reciprocating mechanism, the friction driven type rotating mechanism 21 can realize the rotary driving of the friction driven type rotating mechanism 21 under the premise of static friction, under the linkage rotary transmission of components, the spiral feeding blade 10 is driven to rotate, so that the materials can be input and operated controllably under the action of the same power source, in addition, the friction driven type rotating mechanism 21 in the device is provided with a unidirectional rotating flywheel 214, the material discharge can be realized in the process that the spiral feeding blade 10 moves up in the curve reciprocating mechanism, when the curve reciprocating mechanism 15 moves down, the materials are kept not rotating, and finally, the compacted finished product is obtained, and is taken out by opening the main limit plate 3.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A reciprocating extrusion type material shaping device comprises a main hollow shell (1), a limiting plate mounting groove (2) is arranged at the center of the bottom end of the main hollow shell (1), a main limiting plate (3) which can be taken out is mounted inside the limiting plate mounting groove (2), a reciprocating compression space (4) is arranged at the top end of the limiting plate mounting groove (2), two opposite side surfaces of the reciprocating compression space (4) are respectively provided with a material storage space (12), the top end of one side of each of the two material storage spaces (12) is provided with a feeding hole (13) communicated with the outside, the bottom ends of the two material storage spaces (12) are respectively provided with a funnel type material leaking groove (11), the bottom ends of the two funnel type material leaking grooves (11) are respectively provided with a transverse feeding space (6), the opposite ends of the two feeding spaces (6) are respectively communicated with two sides of the reciprocating compression space (4), and the inside of the main hollow shell (1) is provided with a discharge opening (5) used for communicating the feeding space (6) and the side surface of the reciprocating motion compression space (4), two sides of the main hollow shell (1) are provided with two main rotating shafts (7) which respectively penetrate into the feeding space (6) through bearings, one end of each main rotating shaft (7) positioned outside is provided with a main belt pulley (8), a component mounting space (18) is arranged above the reciprocating motion compression space (4), the top end of the component mounting space (18) is provided with a top component telescopic hole (16), two sides of the main hollow shell (1) are respectively provided with an auxiliary rotating shaft (20) which extends into the component mounting space (18) through bearings, one end of each auxiliary rotating shaft (20) positioned outside is respectively provided with an auxiliary belt pulley (19), and the main belt pulley (8) and the auxiliary belt pulley (19) on each corresponding vertical line are connected through a belt (22), the method is characterized in that: each main rotating shaft (7) is provided with a spiral feeding blade (10) on a shaft body positioned in the feeding space (6), the longitudinal center of the main hollow shell (1) is penetrated from top to bottom to form a top part telescopic hole (16) and a middle part telescopic hole (14) respectively, a curve reciprocating mechanism (15) which can reciprocate up and down is arranged in the top part telescopic hole (16), the part mounting space (18), the middle part telescopic hole (14) and the reciprocating motion compression space (4), the top end of the curve reciprocating mechanism (15) is provided with a main connecting plate (17), the curve reciprocating mechanism (15) is provided with a punch (9) at one end positioned in the reciprocating motion compression space (4), and two pairs of rotating shafts (20) are respectively provided with a friction driven type rotating mechanism (21) at one end positioned in the component mounting space (18).

2. The reciprocating extrusion type material setting device as claimed in claim 1, wherein: the spiral directions of the two spiral feeding blades (10) are arranged according to the feeding direction, namely, the feeding direction formed by the rotation of the spiral feeding blades (10) faces the reciprocating motion compression space (4) on the premise that the spiral feeding blades (10) are driven to rotate by the belt (22).

3. The reciprocating extrusion type material setting device as claimed in claim 1, wherein: the curve reciprocating mechanism (15) comprises a rod body (151) for the curve reciprocating mechanism, a left semi-cylindrical slide rail structure (152) for the curve reciprocating mechanism and a right semi-cylindrical slide rail structure (153) for the curve reciprocating mechanism, the rod body (151) for the curve reciprocating mechanism is respectively provided with the left semi-cylindrical slide rail structure (152) for the curve reciprocating mechanism and the right semi-cylindrical slide rail structure (153) for the curve reciprocating mechanism on opposite sides, and the left semi-cylindrical slide rail structure (152) for the curve reciprocating mechanism and the right semi-cylindrical slide rail structure (153) for the curve reciprocating mechanism are structures which are consistent in structure appearance and symmetrical.

4. The reciprocating extrusion type material setting device as claimed in claim 1, wherein: the friction driven type rotating mechanism (21) comprises a rotating sleeve (211) for a friction driven type rotating mechanism, an annular sliding chute (212) for the friction driven type rotating mechanism, a part mounting hole (213) for the friction driven type rotating mechanism, a unidirectional rotating flywheel (214) for the friction driven type rotating mechanism, a sleeve ring (215) for the friction driven type rotating mechanism and a shaft body mounting hole (216) for the friction driven type rotating mechanism, wherein the annular sliding chute (212) for the friction driven type rotating mechanism is arranged inside the circumferential side surface of the rotating sleeve (211) for the friction driven type rotating mechanism, the part mounting hole (213) for the friction driven type rotating mechanism is arranged in the center inside of the rotating sleeve (211) for the friction driven type rotating mechanism, the unidirectional rotating flywheel (214) for the friction driven type rotating mechanism is sleeved on the inner side of the part mounting hole (213) for the friction driven type rotating mechanism, the center of the unidirectional rotating flywheel (214) for the friction driven type rotating mechanism is provided with a collar (215) for the friction driven type rotating mechanism, and the center of the collar (215) for the friction driven type rotating mechanism is provided with a shaft body mounting hole (216) for the friction driven type rotating mechanism.

5. The reciprocating extrusion type material setting device as claimed in claim 4, wherein: the unidirectional rotation flywheel (214) for a friction driven type rotation mechanism is of a unidirectional rotation structure, and can rotate a rotation sleeve (211) for the friction driven type rotation mechanism along with a collar (215) for the friction driven type rotation mechanism when rotating in a forward direction, and can rotate relatively when not rotating.

6. The reciprocating extrusion type material setting device as claimed in claim 4, wherein: and a shaft body of the auxiliary rotating shaft (20) is arranged in the shaft body mounting hole (216) for the friction driven type rotating mechanism, and the annular sliding chute (212) for the friction driven type rotating mechanism is abutted to the surfaces of the left semi-cylindrical sliding rail structure (152) for the curve reciprocating mechanism and the right semi-cylindrical sliding rail structure (153) for the curve reciprocating mechanism.