CN219258514U - Wire slot clamping and variable-distance same-power conveying mechanism - Google Patents

Abstract

The utility model discloses a wire slot clamping variable-pitch isokinetic conveying mechanism, which comprises a wire slot supporting plate, wherein a fixed side conveying belt assembly and a movable side conveying belt assembly are respectively arranged on the left side and the right side of the wire slot supporting plate, and the movable side conveying belt assembly is arranged on a sliding piece of a transverse moving module through a sliding bottom plate of the movable side conveying belt assembly; the upper parts of the fixed side transmission belt component and the movable side transmission belt component are provided with sleeve type transmission shafts, the left end and the right end of each sleeve type transmission shaft are respectively in transmission connection with the fixed side transmission belt component and the movable side transmission belt component through left bevel gear sets and right bevel gear sets, a side transmission belt driving motor is arranged above the fixed side transmission belt component, and the side transmission belt driving motor is in transmission connection with the left end of each sleeve type transmission shaft through a synchronous belt wheel component. The utility model saves a set of servo motor, simultaneously ensures the rotation synchronism of the two side transmission belts, has small structure and lower cost, improves the time efficiency of machine adjustment and reduces the complexity of programs.

Description

Wire slot clamping and variable-distance same-power conveying mechanism

Technical Field

The utility model belongs to the technical field of wire slot conveying equipment, and particularly relates to a wire slot clamping variable-pitch synchronous power conveying mechanism.

Background

The wire slot, also called wire slot, wiring slot or wire slot, is an electrical tool for standard arrangement of wires such as power wire, data wire, etc., and is fixed on a wall or a ceiling. The trunking finished product is usually cut in sections from a long trunking monolith before shipment. The wire slot feeding equipment can send the wire slot monolith into the wire slot conveying mechanism, and then send the wire slot monolith into the wire slot cutting equipment for cutting and sectioning by the wire slot conveying mechanism.

At present, most of the existing wire slot conveying mechanisms adopt two servo motors to respectively drive two side conveying belts at two sides to respectively rotate, so that the wire slot is driven to be conveyed forwards by clamping forces of the left and right side conveying belts. However, the conventional wire slot conveying mechanism with the double servo motors has the problems of large volume, complex structure, poor synchronism and the like, and is also required to be provided with a servo synchronization program, so that the control is complex, and the time efficiency of the machine adjustment is low.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model provides the wire slot clamping and variable-pitch synchronous power transmission mechanism, which drives two side transmission belts to rotate simultaneously by a set of servo system and ensures the synchronism precision by a mechanical structure, thereby achieving the purposes of simplifying the structure, improving the synchronism and reducing the complexity of a program.

In order to solve the technical problems and achieve the technical effects, the utility model is realized by the following technical scheme:

a wire slot clamping and variable-pitch synchronous power transmission mechanism comprises a transverse moving module, a wire slot supporting plate, a fixed side transmission belt assembly, a moving side transmission belt assembly sliding bottom plate, a side transmission belt driving motor, a synchronous pulley assembly, a telescopic transmission shaft with scalability, a left bevel gear set and a right bevel gear set; the wire slot supporting plate is positioned in the middle, the fixed side conveying belt assembly and the movable side conveying belt assembly are respectively positioned at the left side and the right side of the wire slot supporting plate, and the movable side conveying belt assembly is arranged on a sliding piece of the transverse moving module through a sliding bottom plate of the movable side conveying belt assembly; the sleeve-type transmission shaft is positioned above the fixed-side transmission belt assembly and the movable-side transmission belt assembly, one bevel gear in the left bevel gear set is fixedly sleeved at the left end of the sleeve-type transmission shaft, the other bevel gear in the left bevel gear set is fixedly sleeved at the top end of the front shaft of the fixed-side transmission belt assembly, two bevel gears in the left bevel gear set are meshed up and down, one bevel gear in the right bevel gear set is fixedly sleeved at the right end of the sleeve-type transmission shaft, the other bevel gear in the right bevel gear set is fixedly sleeved at the top end of the front shaft of the movable-side transmission belt assembly, and two bevel gears in the right bevel gear set are meshed up and down; the side transmission belt driving motor is located above the fixed side transmission belt assembly and is in transmission connection with the left end of the sleeve type transmission shaft through the synchronous pulley assembly.

Further, the fixed side transmission belt assembly comprises two fixed side transmission belt fixing upright posts fixedly connected with the table top of the machine frame, a fixed side transmission belt mounting plate is jointly fixed on the right side surface of the two fixed side transmission belt fixing upright posts, a fixed side transmission belt rotating shaft mounting plate is respectively arranged at the upper end and the lower end of the right side surface of the fixed side transmission belt mounting plate, a fixed side transmission belt front rotating shaft is arranged between the front ends of the two fixed side transmission belt rotating shaft mounting plates, a fixed side transmission belt front synchronous roller is fixedly sleeved on the fixed side transmission belt front rotating shaft, the upper end of the fixed side transmission belt front rotating shaft upwards extends out of the upper surface of the fixed side transmission belt rotating shaft mounting plate positioned at the upper layer, a fixed side transmission belt rear rotating shaft is arranged between the rear ends of the fixed side transmission belt rotating shaft mounting plates, a fixed side transmission belt rear synchronous roller is fixedly sleeved on the fixed side transmission belt rear rotating shaft, and a fixed side transmission belt is wound between the fixed side transmission belt front synchronous roller and the fixed side transmission belt rear synchronous roller;

the movable side transmission belt assembly comprises two movable side transmission belt fixing upright posts fixedly connected with the upper surface of a sliding bottom plate of the movable side transmission belt assembly, a movable side transmission belt mounting plate is jointly fixed on the left side surface of the movable side transmission belt fixing upright posts, a movable side transmission belt rotating shaft mounting plate is respectively arranged at the upper end and the lower end of the left side surface of the movable side transmission belt mounting plate, a movable side transmission belt front rotating shaft is arranged between the front ends of the movable side transmission belt rotating shaft mounting plates, movable side transmission belt front synchronous rollers are fixedly sleeved on the movable side transmission belt front rotating shaft, the upper ends of the movable side transmission belt front rotating shafts upwards extend out of the upper surface of the movable side transmission belt rotating shaft mounting plate on the upper layer, movable side transmission belt rear rotating shafts are arranged between the rear ends of the movable side transmission belt rotating shaft mounting plates, movable side transmission belt rear synchronous rollers are fixedly sleeved on the movable side transmission belt rear rotating shafts, and movable side transmission belt rear synchronous rollers are wound between the movable side transmission belt front synchronous rollers and the movable side transmission belt rear synchronous rollers.

Further, the sleeve-type transmission shaft comprises a transmission main shaft and a transmission shaft sleeve, wherein the transmission main shaft is transversely arranged in the transmission shaft sleeve in a non-rotatable manner, the transmission main shaft is positioned on one side of the fixed-side transmission belt assembly, and the transmission shaft sleeve is positioned on one side of the movable-side transmission belt assembly; the upper surface of the fixed side transmission belt rotating shaft mounting plate positioned on the upper layer is provided with a fixed side transmission shaft mounting seat fixing plate, and the fixed side transmission shaft mounting seat is arranged on the fixed side transmission shaft mounting seat fixing plate; a movable side transmission shaft mounting seat fixing plate is arranged on the movable side transmission belt rotating shaft mounting plate positioned on the upper layer, and a movable side transmission shaft mounting seat is arranged on the movable side transmission shaft mounting seat fixing plate; the left end of the transmission main shaft is arranged on the fixed side transmission shaft mounting seat and stretches out leftwards from the fixed side transmission shaft mounting seat, and the right end of the transmission shaft sleeve is arranged on the movable side transmission shaft mounting seat.

Further, the sleeve type transmission shaft is a hexagonal sleeve type transmission shaft, the section shape of the transmission main shaft of the hexagonal sleeve type transmission shaft is hexagonal, the section shape of the inner cavity of the transmission shaft sleeve of the hexagonal sleeve type transmission shaft is hexagonal matched with the section shape of the transmission main shaft, and the transmission main shaft and the transmission shaft sleeve are in clearance fit.

Further, a first bevel gear in the left bevel gear set is fixedly sleeved on the transmission main shaft, the first bevel gear in the left bevel gear set is close to the right side surface of the fixed side transmission shaft mounting seat, a second bevel gear in the left bevel gear set is fixedly sleeved on the top end of the front shaft of the fixed side transmission belt assembly, and the first bevel gear and the second bevel gear in the left bevel gear set are meshed up and down;

the first bevel gear in the right bevel gear set is fixedly sleeved on the sleeve-type transmission shaft, the first bevel gear in the right bevel gear set is close to the left side face of the installation seat of the transmission shaft on the moving side, the second bevel gear in the right bevel gear set is fixedly sleeved on the top end of the front shaft of the transmission belt assembly on the moving side, and the first bevel gear in the right bevel gear set is meshed with the second bevel gear up and down.

Further, the side transmission belt driving motor is installed on the fixing plate of the fixing side transmission shaft installation seat, the driving wheel in the synchronous pulley assembly is installed on the motor shaft of the side transmission belt driving motor, the driven wheel in the synchronous pulley assembly is installed at the left end of the transmission main shaft, and the synchronous belt of the synchronous pulley assembly is wound between the driving wheel and the driven wheel.

Further, the side conveyor belt driving motor is a servo motor.

Further, the transverse moving module is a sliding table electric cylinder.

Further, be provided with side transmission band interval adjustment response subassembly on the slip table jar, side transmission band interval adjustment response subassembly include a plurality of cell type photoelectric sensor and a slice with cell type photoelectric sensor complex anti-dazzling screen, anti-dazzling screen sets up slip table one side of slip table jar, a plurality of cell type photoelectric sensor follows slip table slip direction of slip table jar is in side by side set up slip table jar's base one side, cell type photoelectric sensor with anti-dazzling screen is located the same side of slip table jar, and every cell type photoelectric sensor's mounted position is corresponding with the height of the wire casing of a specification respectively.

Further, an auxiliary guide rail is arranged below the sliding bottom plate of the movable side conveying belt assembly, the arrangement direction of the auxiliary guide rail is the same as that of the transverse moving module, a sliding block is arranged on the auxiliary guide rail, and the upper surface of the sliding block is fixedly connected with the lower surface of the sliding bottom plate of the movable side conveying belt assembly.

The beneficial effects of the utility model are as follows:

1. according to the telescopic sleeve type transmission shaft and the matched scattered gear assembly thereof, a set of servo mechanism can synchronously drive the left side transmission belt and the right side transmission belt to accurately rotate, so that the purpose of conveying the wire grooves is achieved.

2. The cross section of the telescopic sleeve type transmission shaft adopted by the utility model is of a hexagonal structure, the transmission main shaft can transversely move in the transmission shaft sleeve in the left-right direction, and can synchronously rotate in the transmission shaft sleeve in the rotating direction, so that the distance adjustment of the two side transmission belts can be met, the rotation synchronism of the two side transmission belts can be ensured not to be influenced, stable synchronous transmission is realized, the cutting precision of the wire slot is improved, the time effect of machine adjustment is improved, and the program complexity is reduced.

3. According to the utility model, one side of the conveying belt is designed as a fixed part, the other side of the conveying belt is designed as a movable part, and the distance between the movable side of the conveying belt and the fixed side of the conveying belt is realized through one set of transverse moving module, so that the conveying requirements of wire grooves with different sizes are met, and meanwhile, an auxiliary guide rail is additionally arranged on one side of the transverse moving module, so that the transverse moving stability of the movable side of the conveying belt during the distance adjustment can be further improved.

The foregoing description is only an overview of the present utility model, and is intended to provide a better understanding of the present utility model, as it is embodied in the following description, with reference to the preferred embodiments of the present utility model and the accompanying drawings. Specific embodiments of the present utility model are given in detail by the following examples and the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this application, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model. In the drawings:

FIG. 1 is a perspective view of the left front side view of the present utility model;

FIG. 2 is a perspective view of the right front side of the present utility model;

FIG. 3 is a perspective view of the left rear side view of the present utility model;

FIG. 4 is a perspective view of the right rear side view angle of the present utility model;

FIG. 5 is an enlarged front end view of two side belt assemblies of the present utility model;

FIG. 6 is an enlarged rear end view of two side belt assemblies of the present utility model;

FIG. 7 is an enlarged view of the lateral movement module of the present utility model;

fig. 8 is a comparative schematic diagram of three different gauge wire chases.

Detailed Description

The preferred embodiments of the present utility model will be described in detail below with reference to the attached drawings, so that the objects, features and advantages of the present utility model will be more clearly understood. It should be understood that the embodiments shown in the drawings are not intended to limit the scope of the utility model, but rather are merely illustrative of the true spirit of the utility model.

In the following description, for the purposes of explanation of various disclosed embodiments, certain specific details are set forth in order to provide a thorough understanding of the various disclosed embodiments. One skilled in the relevant art will recognize, however, that an embodiment may be practiced without one or more of the specific details. In other instances, well-known devices, structures, and techniques associated with this application may not be shown or described in detail to avoid unnecessarily obscuring the description of the embodiments.

Throughout the specification and claims, unless the context requires otherwise, the word "comprise" and variations such as "comprises" and "comprising" will be understood to be open-ended, meaning of inclusion, i.e. to be interpreted to mean "including, but not limited to.

Reference throughout this specification to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, appearances of the phrases "in one embodiment" or "in an embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

As used in this specification and the appended claims, the singular forms "a," "an," and "the" include plural referents unless the context clearly dictates otherwise. It should be noted that the term "or" is generally employed in its sense including "and/or" unless the context clearly dictates otherwise.

In addition, the technical features of the different embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

Referring to fig. 1-7, the wire slot clamping variable-pitch isokinetic conveying mechanism comprises a transverse moving module 1, a wire slot supporting plate 2, a fixed side conveying belt assembly 3, a movable side conveying belt assembly 4, a movable side conveying belt assembly sliding bottom plate 5, a side conveying belt driving motor 6, a synchronous pulley assembly 7, a telescopic transmission shaft 8, a left bevel gear set 9 and a right bevel gear set 10.

The wire casing backup pad 2 sets up the intermediate position at the frame mesa, fixed side transmission band subassembly 3 with remove side transmission band subassembly 4 and be located respectively the left and right sides of wire casing backup pad 2, fixed side transmission band subassembly 3 direct fixed mounting is in on the frame mesa, remove side transmission band subassembly 4 through remove side transmission band subassembly slip bottom plate 5 setting is in on the slider of lateral shifting module 1, lateral shifting module 1 then fixed mounting is in on the frame mesa.

In this embodiment, the fixed-side conveying belt assembly 3 includes two fixed-side conveying belt fixing posts 301 fixedly connected with the table top of the rack, two fixed-side conveying belt mounting plates 302 are jointly fixed on the right side surfaces of the fixed-side conveying belt fixing posts 301, a fixed-side conveying belt rotating shaft mounting plate 303 is respectively arranged at the upper end and the lower end of the right side surface of the fixed-side conveying belt mounting plate 302, a fixed-side conveying belt front rotating shaft 304 is arranged between the front ends of the fixed-side conveying belt rotating shaft mounting plates 303, a fixed-side conveying belt front synchronizing roller 305 is fixedly sleeved on the fixed-side conveying belt front rotating shaft 304, the upper end of the fixed-side conveying belt front rotating shaft 304 extends upwards to be located on the upper surface of the fixed-side conveying belt rotating shaft mounting plate 303, a fixed-side conveying belt rear rotating shaft 306 is arranged between the rear ends of the fixed-side conveying belt rotating shaft mounting plates 303, and a fixed-side conveying belt rear synchronizing roller 307 is arranged between the fixed-side conveying belt front synchronizing roller 305 and the fixed-side conveying belt rear synchronizing roller 307 in a winding manner.

In this embodiment, the moving-side conveyor belt assembly 4 includes two moving-side conveyor belt fixing posts 401 fixedly connected to the upper surface of the sliding bottom plate 5 of the moving-side conveyor belt assembly, two moving-side conveyor belt fixing posts 401 are fixed with a moving-side conveyor belt mounting plate 402, two moving-side conveyor belt rotating shaft mounting plates 403 are respectively disposed at the upper and lower ends of the left side of the moving-side conveyor belt mounting plate 402, a moving-side conveyor belt front rotating shaft 404 is disposed between the front ends of the two moving-side conveyor belt rotating shaft mounting plates 403, a moving-side conveyor belt front synchronizing roller 405 is fixedly disposed on the moving-side conveyor belt front rotating shaft 404, the upper end of the moving-side conveyor belt front rotating shaft 404 extends upwards to be located on the upper surface of the moving-side conveyor belt rotating shaft mounting plate 403, a moving-side conveyor belt rear rotating shaft 406 is disposed between the rear ends of the moving-side conveyor belt rotating shaft mounting plates 403, a moving-side conveyor belt rear synchronizing roller is fixedly disposed on the moving-side conveyor belt rear rotating shaft 406, and a moving-side conveyor belt rear synchronizing roller 408 is disposed between the moving-side conveyor belt front synchronizing roller 405 and the moving-side conveyor belt rear roller 407.

In this embodiment, the lateral movement module 1 is a sliding table electric cylinder, and the distance between the movable side conveyor belt assembly 4 and the fixed side conveyor belt assembly 3 is adjusted by the lateral movement of the sliding table electric cylinder. The movable side transmission belt assembly 4 and the fixed side transmission belt assembly 3 form a channel for transmitting the trunking, and the trunking supporting plate 2 is positioned in the channel and is close to one side of the fixed side transmission belt assembly 3, so as to provide support for the bottom of the trunking during trunking transmission.

In this embodiment, be provided with side transmission band interval adjustment response subassembly on the slip table jar, side transmission band interval adjustment response subassembly include 3 cell type photoelectric sensor 15 and a slice with cell type photoelectric sensor 15 complex anti-dazzling screen 16, anti-dazzling screen 16 sets up slip table one side of slip table jar, 3 cell type photoelectric sensor 15 follows slip table slip direction of slip table jar is in side by side slip table jar base one side, cell type photoelectric sensor 15 with anti-dazzling screen 16 is located the same side of slip table jar, and the mounted position of every cell type photoelectric sensor 15 corresponds with the height of the wire casing of a specification respectively. That is, when the sliding table of the sliding table electric cylinder moves to the first one of the groove-type photoelectric sensors 15 from the left, the channel width between the moving-side conveyor belt assembly 4 and the fixed-side conveyor belt assembly 3 is adapted to one of the lower-height line grooves, when the sliding table of the sliding table electric cylinder moves to the second one of the groove-type photoelectric sensors 15 from the left, the channel width between the moving-side conveyor belt assembly 4 and the fixed-side conveyor belt assembly 3 is adapted to one of the medium-height line grooves, and when the sliding table of the sliding table electric cylinder moves to the third one of the groove-type photoelectric sensors 15 from the left, the channel width between the moving-side conveyor belt assembly 4 and the fixed-side conveyor belt assembly 3 is adapted to one of the higher-height line grooves.

In this embodiment, an auxiliary guide rail 17 is further disposed below the sliding bottom plate 5 of the moving-side conveying belt assembly, the auxiliary guide rail 17 is fixedly mounted on the table top of the frame, the setting direction of the auxiliary guide rail 17 is the same as that of the transverse moving module 1, a sliding block 18 is disposed on the auxiliary guide rail 17, and the upper surface of the sliding block 18 is fixedly connected with the lower surface of the sliding bottom plate 5 of the moving-side conveying belt assembly, so that the stability of the moving-side conveying belt assembly 4 during transverse moving can be improved.

In this embodiment, the sleeve-type transmission shaft 8 is located above the fixed-side transmission belt assembly 3 and the moving-side transmission belt assembly 4, the sleeve-type transmission shaft 8 includes a transmission main shaft 801 and a transmission shaft sleeve 802, the transmission main shaft 801 is disposed in the transmission shaft sleeve 802, but the matching relationship between the transmission main shaft 801 and the transmission shaft sleeve 802 needs to be satisfied, and the transmission main shaft 801 can move laterally in the transmission shaft sleeve 802 and can drive the transmission shaft sleeve 802 to rotate. The transmission main shaft 801 is positioned on the side of the fixed-side transmission belt assembly 3, and the transmission shaft sleeve 802 is positioned on the side of the movable-side transmission belt assembly 4; the upper surface of the fixed side transmission belt rotating shaft mounting plate 303 positioned on the upper layer is provided with a fixed side transmission shaft mounting seat fixing plate 11, and the fixed side transmission shaft mounting seat 12 is arranged on the fixed side transmission shaft mounting seat fixing plate 11; a movable side transmission shaft mounting seat fixing plate 13 is arranged on the movable side transmission belt rotating shaft mounting plate 403 positioned on the upper layer, and a movable side transmission shaft mounting seat 14 is arranged on the movable side transmission shaft mounting seat fixing plate 13; the left end of the transmission main shaft 801 is mounted on the fixed-side transmission shaft mounting seat 12 and extends out of the fixed-side transmission shaft mounting seat 12 to the left, and the right end of the transmission shaft sleeve 802 is mounted on the moving-side transmission shaft mounting seat 14.

As a further preferred embodiment, the sleeve-type transmission shaft 8 is a hexagonal sleeve-type transmission shaft, the cross-sectional shape of the transmission main shaft 801 of the hexagonal sleeve-type transmission shaft is a hexagon, the cross-sectional shape of the inner cavity of the transmission shaft sleeve 802 of the hexagonal sleeve-type transmission shaft is a hexagon matched with the cross-sectional shape of the transmission main shaft 801, and a clearance fit is formed between the transmission main shaft 801 and the transmission shaft sleeve 802. The hexagonal cross section may enable the transmission main shaft 801 to be configured in the left-right direction and to be configured in a tight manner in the rotation direction when the transmission main shaft 801 is in the transmission shaft sleeve 802, so that the transmission main shaft 801 may not only move laterally in the transmission shaft sleeve 802, but also drive the transmission shaft sleeve 802 to rotate. The cross section of the sleeve-type transmission shaft 8 can also be polygonal, such as octagonal, etc., which can meet the assembly requirements.

In this embodiment, a first bevel gear in the left bevel gear set 9 is fixedly sleeved on the transmission main shaft 801, and the first bevel gear in the left bevel gear set 9 is close to the right side surface of the fixed side transmission shaft mounting seat 12, a second bevel gear in the left bevel gear set 9 is fixedly sleeved on the top end of the front shaft of the fixed side transmission belt assembly 3, and the first bevel gear in the left bevel gear set 9 is meshed with the second bevel gear up and down; the first bevel gear of the right bevel gear set 10 is fixedly sleeved on the sleeve-type transmission shaft 8, the first bevel gear of the right bevel gear set 10 is close to the left side surface of the movable side transmission shaft mounting seat 14, the second bevel gear of the right bevel gear set 10 is fixedly sleeved on the top end of the front shaft of the movable side transmission belt assembly 4, and the first bevel gear of the right bevel gear set 10 is meshed with the second bevel gear up and down.

In this embodiment, the side transmission belt driving motor 6 is mounted on the fixing plate 11 of the fixing side transmission shaft mounting seat, and the side transmission belt driving motor 6 is a servo motor. The driving wheel in the synchronous pulley assembly 7 is installed on the motor shaft of the side transmission belt driving motor 6, the driven wheel in the synchronous pulley assembly 7 is installed at the left end of the transmission main shaft 801, and the synchronous belt of the synchronous pulley assembly 7 is wound between the driving wheel and the driven wheel.

The working principle of the utility model is as follows:

referring to fig. 1-7, firstly, the sliding table transverse movement position of the transverse movement module 1 is controlled to drive the left and right movement of the movable side transmission belt assembly 4, so that the distance between the movable side transmission belt assembly 4 and the fixed side transmission belt assembly 3 is adjusted, namely, the width of a wire slot transmission channel is adjusted, and the transmission requirements of wire slots with different sizes are met. Referring to fig. 8, the dimensions of the trunking are shown in fig. 8 for 3 different gauge sizes.

In the process of moving the moving-side conveyor belt assembly 4 left and back, the auxiliary guide rail 17 provides auxiliary support for the moving-side conveyor belt assembly 4, so that the movement stability of the moving-side conveyor belt assembly 4 can be effectively improved. Meanwhile, since the sleeve type transmission shaft 8 has scalability, the transmission main shaft 801 moves laterally left and right in the transmission shaft sleeve 802, so that the penetration length of the transmission main shaft 801 in the transmission shaft sleeve 802 is synchronously changed with the change of the distance between the movable side transmission belt assembly 4 and the fixed side transmission belt assembly 3.

After the width of the slot conveying channel is adjusted, the side conveying belt driving motor 6 starts to work, the side conveying belt driving motor 6 drives the transmission main shaft 801 to rotate through the synchronous pulley assembly 7, and the transmission main shaft 801 does not slip or idle in the transmission shaft sleeve 802 due to the polygonal section of the transmission main shaft 801 and drives the transmission shaft sleeve 802 to rotate together, so that the whole sleeve type transmission shaft 8 normally rotates, and synchronous rotation of the left bevel gear set 9 and the right bevel gear set 10 is realized.

The left bevel gear set 9 and the right bevel gear set 10 synchronously drive the synchronous rotation of the fixed side transmission belt 308 and the movable side transmission belt 408 through the fixed side transmission belt front rotating shaft 304 and the movable side transmission belt front rotating shaft 404 respectively, so that the left clamping force and the right clamping force of the wire slot drive the wire slot to convey forwards.

The utility model can be arranged at a feed inlet and a discharge outlet of a wire groove cutting station in wire groove automatic cutting equipment so as to meet the cutting and conveying requirements of wire grooves with different sizes.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. A wire casing centre gripping displacement is with power conveying mechanism, its characterized in that: the device comprises a transverse moving module (1), a wire slot supporting plate (2), a fixed side transmission belt assembly (3), a movable side transmission belt assembly (4), a movable side transmission belt assembly sliding bottom plate (5), a side transmission belt driving motor (6), a synchronous pulley assembly (7), a telescopic transmission shaft (8) with scalability, a left bevel gear set (9) and a right bevel gear set (10); the wire slot supporting plate (2) is positioned in the middle, the fixed side conveying belt assembly (3) and the movable side conveying belt assembly (4) are respectively positioned at the left side and the right side of the wire slot supporting plate (2), and the movable side conveying belt assembly (4) is arranged on a sliding piece of the transverse moving module (1) through the movable side conveying belt assembly sliding bottom plate (5); the sleeve-type transmission shaft (8) is positioned above the fixed-side transmission belt assembly (3) and the movable-side transmission belt assembly (4), one bevel gear in the left bevel gear set (9) is fixedly sleeved at the left end of the sleeve-type transmission shaft (8), the other bevel gear in the left bevel gear set (9) is fixedly sleeved at the front shaft top end of the fixed-side transmission belt assembly (3), two bevel gears in the left bevel gear set (9) are meshed up and down, one bevel gear in the right bevel gear set (10) is fixedly sleeved at the right end of the sleeve-type transmission shaft (8), the other bevel gear in the right bevel gear set (10) is fixedly sleeved at the front shaft top end of the movable-side transmission belt assembly (4), and two bevel gears in the right bevel gear set (10) are meshed up and down; the side transmission belt driving motor (6) is located above the fixed side transmission belt assembly (3), and the side transmission belt driving motor (6) is in transmission connection with the left end of the sleeve type transmission shaft (8) through the synchronous pulley assembly (7).

2. The trunking clamp pitch-changing homokinetic power transmission mechanism of claim 1, wherein: the fixed side transmission belt assembly (3) comprises two fixed side transmission belt fixing upright posts (301) fixedly connected with a rack table top, a fixed side transmission belt mounting plate (302) is jointly fixed on the right side surface of the fixed side transmission belt fixing upright posts (301), a fixed side transmission belt rear rotating shaft (306) is respectively arranged at the upper end and the lower end of the right side surface of the fixed side transmission belt mounting plate (302), a fixed side transmission belt front rotating shaft (304) is arranged between the front ends of the two fixed side transmission belt rotating shaft mounting plates (303), a fixed side transmission belt front synchronous roller (305) is fixedly sleeved on the fixed side transmission belt front rotating shaft (304), the upper end of the fixed side transmission belt front rotating shaft (304) upwards extends out of the upper surface of the fixed side transmission belt rotating shaft mounting plate (303) positioned on the upper layer, a fixed side transmission belt rear rotating shaft (306) is arranged between the rear ends of the fixed side transmission belt rotating shaft mounting plate (303), and a fixed side transmission belt rear synchronous roller (307) is fixedly sleeved on the fixed side transmission belt rear rotating shaft (306), and a fixed side transmission belt synchronous roller (308) is arranged between the fixed side transmission belt front synchronous roller (305);

the utility model provides a synchronous roller (408) is equipped with in the back of the moving side transmission band (synchronous roller (407), including moving side transmission band (synchronous roller) is equipped with in the front of the moving side transmission band (synchronous roller (404), and the upper end of moving side transmission band front rotary shaft (404) upwards stretches out the upper surface that is located upper strata moving side transmission band pivot (403), be provided with moving side transmission band back rotary shaft (406) between the rear end of moving side transmission band pivot (403), moving side transmission band back fixed cover is equipped with moving side transmission band front rotary shaft (404) between the front end of moving side transmission band pivot (403), moving side transmission band front rotary shaft (404) is equipped with moving side transmission band front synchronous roller (405), and moving side transmission band front rotary shaft (synchronous roller (407) is equipped with in the back of moving side transmission band (synchronous roller) is equipped with in the front of moving side transmission band (synchronous roller (407).

3. The trunking clamp pitch-changing homokinetic force transfer mechanism of claim 2, wherein: the sleeve type transmission shaft (8) comprises a transmission main shaft (801) and a transmission shaft sleeve (802), wherein the transmission main shaft (801) is transversely arranged in the transmission shaft sleeve (802) in a non-rotatable manner, the transmission main shaft (801) is positioned on one side of the fixed side transmission belt assembly (3), and the transmission shaft sleeve (802) is positioned on one side of the movable side transmission belt assembly (4); the upper surface of the fixed side transmission belt rotating shaft mounting plate (303) positioned on the upper layer is provided with a fixed side transmission shaft mounting seat fixing plate (11), and the fixed side transmission shaft mounting seat (12) is arranged on the fixed side transmission shaft mounting seat fixing plate (11); a movable side transmission shaft mounting seat fixing plate (13) is arranged on the movable side transmission belt rotating shaft mounting plate (403) positioned on the upper layer, and a movable side transmission shaft mounting seat (14) is arranged on the movable side transmission shaft mounting seat fixing plate (13); the left end of the transmission main shaft (801) is mounted on the fixed side transmission shaft mounting seat (12) and stretches out of the fixed side transmission shaft mounting seat (12) leftwards, and the right end of the transmission shaft sleeve (802) is mounted on the movable side transmission shaft mounting seat (14).

4. A wire chase clamping variable pitch homokinetic power transmission mechanism as defined in claim 3, wherein: the sleeve type transmission shaft (8) is a hexagonal sleeve type transmission shaft, the section of the transmission main shaft (801) of the hexagonal sleeve type transmission shaft is hexagonal, the section of the inner cavity of the transmission shaft sleeve (802) of the hexagonal sleeve type transmission shaft is hexagonal matched with the section of the transmission main shaft (801), and the transmission main shaft (801) and the transmission shaft sleeve (802) are in clearance fit.

5. A wire chase clamping variable pitch homokinetic power transmission mechanism as defined in claim 3, wherein: the first bevel gear in the left bevel gear set (9) is fixedly sleeved on the transmission main shaft (801), the first bevel gear in the left bevel gear set (9) is close to the right side surface of the fixed side transmission shaft mounting seat (12), the second bevel gear in the left bevel gear set (9) is fixedly sleeved on the top end of the front shaft of the fixed side transmission belt assembly (3), and the first bevel gear in the left bevel gear set (9) is meshed with the second bevel gear up and down;

the first bevel gear in the right bevel gear set (10) is fixedly sleeved on the sleeve-type transmission shaft (8), the first bevel gear in the right bevel gear set (10) is close to the left side face of the movable side transmission shaft mounting seat (14), the second bevel gear in the right bevel gear set (10) is fixedly sleeved on the top end of the front shaft of the movable side transmission belt assembly (4), and the first bevel gear and the second bevel gear in the right bevel gear set (10) are meshed up and down.

6. A wire chase clamping variable pitch homokinetic power transmission mechanism as defined in claim 3, wherein: the side transmission belt driving motor (6) is installed on the fixed side transmission shaft installation seat fixing plate (11), a driving wheel in the synchronous pulley assembly (7) is installed on a motor shaft of the side transmission belt driving motor (6), a driven wheel in the synchronous pulley assembly (7) is installed at the left end of the transmission main shaft (801), and a synchronous belt of the synchronous pulley assembly (7) is wound between the driving wheel and the driven wheel.

7. The trunking clamp pitch-changing homokinetic force transfer mechanism of claim 6, wherein: the side transmission belt driving motor (6) is a servo motor.

8. The trunking clamp pitch-changing homokinetic power transmission mechanism of claim 1, wherein: the transverse moving module (1) is a sliding table electric cylinder.

9. The trunking clamp pitch-shifting homokinetic power transmission mechanism of claim 8, wherein: the novel electric wire groove is characterized in that a side transmission belt distance adjusting induction component is arranged on the sliding table electric cylinder and comprises a plurality of groove-shaped photoelectric sensors (15) and a piece of shading sheet (16) matched with the groove-shaped photoelectric sensors (15), the shading sheet (16) is arranged on one side of the sliding table electric cylinder, the groove-shaped photoelectric sensors (15) are arranged on one side of a base of the sliding table electric cylinder side by side along the sliding direction of the sliding table electric cylinder, the groove-shaped photoelectric sensors (15) and the shading sheet (16) are arranged on the same side of the sliding table electric cylinder, and the installation position of each groove-shaped photoelectric sensor (15) corresponds to the height of a wire groove of one specification.

10. The trunking clamp pitch-changing homokinetic power transmission mechanism of claim 1, wherein: the mobile side transmission belt assembly sliding bottom plate (5) is characterized in that an auxiliary guide rail (17) is arranged below the mobile side transmission belt assembly sliding bottom plate (5), the arrangement direction of the auxiliary guide rail (17) is the same as that of the transverse movement module (1), a sliding block (18) is arranged on the auxiliary guide rail (17), and the upper surface of the sliding block (18) is fixedly connected with the lower surface of the mobile side transmission belt assembly sliding bottom plate (5).

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