SUMMERY OF THE UTILITY MODEL
The utility model provides a line position motion aims at solving the comparatively complicated and comparatively loaded down with trivial details problem of procedure of current line position motion structure.
In order to solve the above technical problem, an aspect of the present invention provides a slide motion mechanism, including: the pushing assembly comprises a first pushing piece, a second pushing piece, a first line seat and a second line seat, wherein the second pushing piece is arranged between the first line seat and the second line seat, and the first pushing piece can reciprocate in a sliding groove arranged in the first line seat to generate friction force so as to drive the first line seat, the second pushing piece and the second line seat to complete a first preset action; and the core pulling assembly is connected with the second slide seat and is driven by the pushing assembly to complete a second preset action so as to complete side core pulling movement or side core pulling reset movement.
Furthermore, the core pulling assembly comprises a first row of inserting needles and a second row of inserting needles, and the first row of inserting needles and the second row of inserting needles are in sliding connection with the second row of seats, so that the first row of inserting needles and the second row of inserting needles complete side core pulling movement or side core pulling reset movement.
Furthermore, a pressing block is arranged on the second slide seat, and one end of the first slide insert pin and one end of the second slide insert pin can be connected to the second slide seat through the pressing block and a first fastener on the pressing block.
Furthermore, a guide groove consistent with the second preset angle is formed in the second slide seat, and the first slide insert pin and the second slide insert pin can complete side core pulling movement or side core pulling reset movement under the driving of the pushing assembly by means of the guide groove, the pressing block and the first fastener.
Furthermore, two convex blocks are arranged in the sliding groove, the two convex blocks are telescopic and symmetrical with each other, and friction force can be generated when the first pushing piece reciprocates in the sliding groove by means of the two convex blocks.
Furthermore, the sliding groove is obliquely arranged in the first displacement seat at a first preset inclined angle, and the first pushing piece can reciprocate in the sliding groove at the first preset inclined angle.
Furthermore, a convex part is arranged at the upper end of the first pushing part and used for being not connected with the horizontal plane of the first displacement seat when the first pushing part slides to the bottom of the sliding chute through the two convex blocks.
Further, the second pushing member is fixedly connected with the first position seat through a second fastening member.
Furthermore, the second pushing piece and the second traveling seat are in sliding connection with a second preset inclined angle.
Furthermore, the slide mechanism further comprises a shovel base, and the shovel base is connected with the first slide seat.
The slide motion mechanism disclosed by the utility model generates friction force by reciprocating a first pushing piece in the pushing assembly in a chute arranged in the first slide seat, thereby driving the first slide seat, the second pushing piece and the second slide seat to complete a first preset action; the core pulling assembly is connected with the second slide seat, so that the core pulling assembly can complete second preset action under the driving of the pushing assembly, the whole slide motion mechanism is simple in structure, and slide motions in multiple composite directions can be converted into slide motions in an angle direction during side core pulling motion or side core pulling reset motion, and therefore the processing procedure is simplified. The utility model discloses a line position motion has solved the complicated and loaded down with trivial details problem of procedure of current line position motion structure.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, of the embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
It will be understood that the terms "comprises" and/or "comprising," when used in this specification and the appended claims, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.
It is also to be understood that the terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in the specification and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.
It should be further understood that the term "and/or" as used in the specification and the appended claims refers to any and all possible combinations of one or more of the associated listed items, and includes such combinations.
Fig. 1 is a schematic perspective view of a slide motion mechanism according to an embodiment of the present invention; FIG. 2 is a schematic cross-sectional view of the side core pulling movement of the slide movement mechanism shown in FIG. 1; FIG. 3 is a schematic view of the side core pulling movement of the slide movement mechanism shown in FIG. 1; FIG. 4 is a schematic cross-sectional view of the side core return movement of the slide movement mechanism shown in FIG. 1; fig. 5 is a schematic view of the side core back reset movement of the slide moving mechanism shown in fig. 1. As shown in fig. 1 to 5, the slide moving mechanism 10 of the present embodiment includes a pushing assembly 11 and a core back assembly 12. The pushing assembly 11 includes a first pushing member 111, a second pushing member 112, a first traveling seat 113 and a second traveling seat 114, wherein the second pushing member 112 is disposed between the first traveling seat 113 and the second traveling seat 114, and the first pushing member 111 can reciprocate in a sliding slot 1131 disposed in the first traveling seat 113 to generate a friction force, so as to drive the first traveling seat 113, the second pushing member 112 and the second traveling seat 114 to complete a first predetermined action (moving in a direction of an arrow M1 shown in fig. 2 or moving in a direction of an arrow M3 shown in fig. 4); the core-pulling assembly 12 is connected to the second traveling seat 114, and is driven by the pushing assembly 11 to complete a second preset action (moving along the direction of the arrow M2 shown in fig. 3 or the direction of the arrow M4 shown in fig. 5), so as to complete the side core-pulling movement or the side core-pulling reset movement. In this embodiment, the first pushing member 111 is an inclined guide pillar, and the second pushing member 112 is a T-block. In specific implementation, the first pushing member 111 of the pushing assembly 11 reciprocates in a slide channel 1131 of the first traveling seat 113 to generate friction force, so as to drive the first traveling seat 113, the second pushing member 112, and the second traveling seat 114 to perform the first predetermined action (moving in the direction of arrow M1 shown in fig. 2 or moving in the direction of arrow M3 shown in fig. 4); the core pulling assembly 12 is connected to the second slide seat 114, so that the core pulling assembly 12 is driven by the pushing assembly 11 to complete the second preset action (moving along the direction of an arrow M2 shown in fig. 3 or along the direction of an arrow M4 shown in fig. 5), the structure of the whole slide movement mechanism is simple, and the slide movement in multiple compound directions during the side core pulling movement or the side core pulling reset movement can be converted into the slide movement in one horizontal direction, thereby simplifying the processing procedure.
In an embodiment, for example, in the embodiment, the core back assembly 12 includes a first row of insert pins 121 and a second row of insert pins 122, and the first row of insert pins 121 and the second row of insert pins 122 are slidably connected to the second row of seat 114, so that the first row of insert pins 121 and the second row of insert pins 122 complete a side core back movement or a side core back reset movement. Specifically, a pressing block 1141 is disposed on the second slide seat 114, and one end of the first slide insert 121 and one end of the second slide insert 122 can be connected to the second slide seat 114 by the pressing block 1141 and a first fastening member 1143 disposed on the pressing block 1141. More specifically, the second slide seat 114 is provided with a guide slot 1142 consistent with the second preset angle, and the first slide insert pin 121 and the second slide insert pin 122 can complete the side core-pulling movement or the side core-pulling reset movement under the driving of the pushing assembly 11 by the guide slot 1142, the pressing block 1141 and the first fastening member 1143. In this embodiment, the first fastening member 1143 is a screw, and in other embodiments, the first fastening member 1143 may also be a bolt, and only one end of the first threading insert 121 and one end of the second threading insert 122 need to be fixedly connected to the second threading seat 114 through the first fastening member 1143 and the pressing block 1141.
In an embodiment, for example, in the embodiment, two protrusions 1132 are disposed in the sliding channel 1131, and the two protrusions 1132 are retractable and symmetrical to each other, so that the two protrusions 1132 can generate friction when the first pushing member 111 reciprocates in the sliding channel 1131. Specifically, the sliding groove 1131 is disposed in the first position seat 113 at a first preset inclination angle, and the first pushing member 111 reciprocates in the sliding groove 1131 at the first preset inclination angle. In this embodiment, a protrusion 1111 is disposed at an upper end of the first pushing member 111, and the protrusion 1111 is configured to not engage with the horizontal surface of the first seat 113 when the first pushing member 111 slides to the bottom of the sliding channel 1131 through the two protrusions 1132, that is, the protrusion 1132 is above the first seat 113, so that an operator can conveniently hold the protrusion 1111 of the first pushing member 111 by hand to make the first pushing member 111 reciprocate in the sliding channel 1131 at the first preset inclined angle.
In one embodiment, such as this embodiment, the second pusher 112 is fixedly coupled to the first seat 113 via a second fastener 1133. The second pushing member 112 is slidably connected to the second traveling seat 114 at a second predetermined inclined angle. Specifically, the second pushing member 112 can be locked at a protrusion 1132 by the second fastening member 1133, so that the first pushing member 111 reciprocates in the sliding groove 1131 to move the first and second seats 113 and 112. In this embodiment, the second fastening member 1133 is a screw. In other embodiments, the second fastener 1133 may also be a bolt.
In an embodiment, for example, in this embodiment, the slide mechanism further includes a shovel base 13, and the shovel base 13 is connected to the first slide base 113. Specifically, the shovel base 13 is disposed behind the pushing assembly 11 to abut against the pushing assembly 11, and when the slide mechanism performs the side core pulling or side core pulling reset motion, the shovel base 13 may prevent the pushing assembly 11 and the core pulling assembly 12 from shifting due to the side core pulling or side core pulling reset motion.
The following describes in detail the side core pulling movement and the side core pulling reset movement of the slide movement mechanism.
As can be seen from fig. 2 and 3, when the first pushing assembly 11 is pulled upwards along the sliding groove 1131 in the first seat 113 to generate a pulling force F1, a downward frictional force is generated in a direction opposite to the pulling force F1, so as to drive the first seat 113 and the second pushing member 112 to move toward the shovel base 13; as the second pushing member 112 is slidably connected to the second traveling seat 114 at the second preset inclination angle, the second pushing member 112 is further driven to move toward the shovel base 13, and at this time, the first preset action M1 of side core pulling movement is completed; the second slide seat 114 moves toward the shovel base 13 to drive the first slide insert pin 121 and the second slide insert pin 122 to move along the guide groove 1142, thereby completing the side core pulling movement. In this embodiment, the guide slot 1142 is arranged in the direction of the second preset angle, so that the slide moving mechanism can complete the side core pulling movement through the first preset movement M1 and the second preset movement M2 of the side core pulling movement.
As shown in fig. 4 and 5, when the first pushing assembly 11 pushes downwards along the sliding groove 1131 in the first seat 113 to generate a pushing force F2, an upward friction force is generated in a direction opposite to the pushing force F2, so as to drive the first seat 113 and the second pushing member 112 to move in a direction opposite to the direction of the shovel base 13; as the second pushing member 112 is slidably connected to the second traveling seat 114 at the second preset inclination angle, the second pushing member 112 is further driven to move in the opposite direction of the shovel base 13, and at this time, a first preset action M3 of the side core pulling reset movement is completed; the second slide seat 114 moves towards the shovel base 13 to push the first slide insert needle 121 and the second slide insert needle 122 to move towards the direction opposite to the shovel base 13, that is, to move forwards, so as to complete the side core pulling reset movement. In this embodiment, the first preset action M3 and the second preset action M4 after the side core back reset movement can make the slide moving mechanism complete the side core back reset movement.
The slide motion mechanism provided by the utility model generates friction force by reciprocating motion of the first pushing piece in the pushing assembly in a chute arranged in the first slide seat, thereby driving the first slide seat, the second pushing piece and the second slide seat to complete a first preset action; the core pulling assembly is connected with the second slide seat, so that the core pulling assembly can complete a second preset action under the driving of the pushing assembly, the whole slide motion mechanism is simple in structure, and the processing procedure is simplified. Specifically, the utility model discloses a first impeller upwards or the downstream produces frictional force in a spout that first impeller was established in the seat of the first line to drive seat of the first line, second impeller and the seat of the second line and move or move to shovel base opposite direction to the direction of shovel base, thereby drive the needle is inlayed to the first line position and the needle is inlayed to the second line position and move or move to shovel base opposite direction, and then accomplish the side and loose core the motion or the reset motion of loosing core to the side. Compared with the existing slide motion mechanism, the whole slide motion mechanism is simpler in structure, and slide motion in multiple composite directions can be converted into slide motion in an angle direction during side core pulling motion or side core pulling reset motion, so that the processing procedure is simplified, and the cost of the die is reduced. The utility model discloses a line position motion has solved the complicated and loaded down with trivial details problem of procedure of current line position motion structure.
The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of various equivalent modifications or replacements within the technical scope of the present invention, and these modifications or replacements should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.