CN219133315U - Modularized double-steel-belt continuous press - Google Patents

Abstract

The utility model provides a modularized double-steel-belt continuous press, which comprises a driving mechanism, a driven mechanism, an upper steel belt 3, a lower steel belt 1, a connecting frame and a plurality of processing modules 9, wherein the plurality of processing modules 9 are arranged in the connecting frame in parallel along the length direction of the connecting frame, the adjacent processing modules 9 are detachably connected, the driving mechanism is arranged at one end of the connecting frame, the driven mechanism is arranged at the other end of the connecting frame, the upper steel belt 3 is sleeved outside the upper driving mechanism, the upper processing modules and the upper driven mechanism, and the lower steel belt 1 is sleeved outside the lower driving mechanism, the lower processing modules and the lower driven mechanism; the driving mechanism can drive the upper steel belt 3 and the lower steel belt 1 to run, so that materials to be processed are input into the processing module 9 from the feed inlet.

Description

Modularized double-steel-belt continuous press

Technical Field

The utility model relates to the field of composite material production, in particular to a modularized double-steel-belt continuous press.

Background

With the development of technology, various novel composite materials which need to be manufactured at high pressure and high temperature are endless.

However, the processing modules of the existing processing equipment are relatively fixed, so that composite materials with different production processes are difficult to meet, and the processing equipment is required to be customized in a modularized manner to meet the production processes of various composite materials so as to meet the requirements of most production processes.

The patent document with the publication number of CN217531980U discloses a double-steel-belt continuous flat press for steel belt processing, and aims at solving the problems that in the prior art, when the double-steel-belt flat press presses steel belts, the pressure of the double-steel-belt flat press is generally inconvenient to adjust, when the pressure is insufficient, the quality problem of the steel belts can be caused, thereby the reworking of the steel belts is caused, the normal operation and the working efficiency of the double-steel-belt flat press can be influenced, the scheme is provided, the double-steel-belt continuous flat press comprises a double-steel-belt flat press, feeding ports are formed in the left inner wall and the rear inner wall of the double-steel-belt flat press, and a fixed plate is fixedly connected to the front inner wall of the double-steel-belt flat press. However, the device cannot realize modularized customization and cannot meet various production process requirements.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide a modularized double-steel-belt continuous press.

The modularized double-steel-belt continuous press provided by the utility model comprises a driving mechanism, a driven mechanism, an upper steel belt, a lower steel belt, a connecting frame and a plurality of processing modules, wherein the processing modules can be customized according to a product process;

the processing modules are arranged in the connecting frame in parallel along the length direction of the connecting frame and are detachably connected with the connecting frame, adjacent processing modules are not connected or detachably connected, the driving mechanism is arranged at one end of the connecting frame and comprises an upper driving mechanism and a lower driving mechanism, the driven mechanism is arranged at the other end of the connecting frame and comprises an upper driven mechanism and a lower driven mechanism;

the processing module comprises an upper processing module and a lower processing module, wherein the upper steel belt is sleeved outside the upper driving mechanism, the upper processing module and the upper driven mechanism, and the lower steel belt is sleeved outside the lower driving mechanism, the lower processing module and the lower driven mechanism;

a feeding hole is formed between the upper driving mechanism and the lower driving mechanism, and a discharging hole is formed between the upper driven mechanism and the lower driven mechanism; or a discharge hole is formed between the upper driving mechanism and the lower driving mechanism, and a feed inlet is formed between the upper driven mechanism and the lower driven mechanism;

the driving mechanism can drive the upper steel belt and the lower steel belt to operate, so that materials to be processed are input into the processing module from the feeding port, processed materials are output from the discharging port, and the operation directions of the upper steel belt and the lower steel belt are opposite.

Preferably, the upper driving mechanism comprises a second driving roller, and the lower driving mechanism comprises a first driving roller;

the second driving roller can drive the upper steel belt to run through rotation, the first driving roller can drive the lower steel belt to run through rotation, and the rotation direction between the first driving roller and the second driving roller is opposite.

Preferably, the driving mechanism further comprises a second rack, and the second rack is fixedly arranged at one end of the connecting frame;

the first driving roller is arranged at the lower part of the second rack, and the second driving roller is arranged at the upper part of the second rack.

Preferably, the upper driven mechanism comprises a second driven roller, and the lower driven mechanism comprises a first driven roller;

the second driven roller can rotate under the drive of the upper steel belt, the first driven roller can rotate under the drive of the lower steel belt, and the rotation direction between the second driven roller and the first driven roller is opposite.

Preferably, the driven mechanism further comprises a first rack, and the first rack is fixedly arranged at the other end of the connecting frame;

the first driven roller is arranged at the lower part of the first rack, and the second driven roller is arranged at the upper part of the first rack.

Preferably, a feed inlet is formed between the second driven roller and the first driven roller, and the first driven roller is far away from the processing module than the second driven roller in a longitudinal projection.

Preferably, the device further comprises an oil cylinder for tensioning the upper steel belt and the lower steel belt, wherein the oil cylinder is arranged in the driven mechanism and is connected with the upper steel belt and the lower steel belt.

Preferably, the processing module is capable of performing a heating function, a pressurizing function, or a heating and pressurizing function.

Preferably the connection frame comprises an upper longitudinal beam, a transverse beam, a vertical beam and a lower longitudinal beam;

the upper longitudinal beams and the lower longitudinal beams are arranged in parallel, the upper longitudinal beams are connected with each other through transverse beams, the upper longitudinal beams and the lower longitudinal beams are connected with each other through vertical beams, and the processing modules are arranged in parallel along the length direction of the upper longitudinal beams;

the upper longitudinal beam and the lower longitudinal beam are detachably connected with the processing module.

Preferably, the device further comprises an overhaul mechanism, wherein the overhaul mechanism comprises a first overhaul guide rail, an overhaul support and a second overhaul guide rail, and a module guide rail perpendicular to the material conveying direction is arranged at the bottom of the processing module;

when the processing module needs to be overhauled, the first overhauling guide rail and the second overhauling guide rail are respectively connected with the two ends of the module guide rail and are arranged in parallel with the module guide rail, and the overhauling bracket is arranged on the second overhauling guide rail;

the end part of the overhaul support is fixedly connected with the processing module to be overhauled, a first gap is formed in the end part of the overhaul support, and the overhaul support can drive the processing module to be overhauled to move from an initial position to an overhaul position;

when the processing module to be overhauled is positioned at the initial position, the processing module to be overhauled is positioned on the module guide rail, and at the moment, the upper steel belt and the lower steel belt are positioned in the processing module to be overhauled;

when the processing module to be overhauled is located at the overhauling position, the processing module to be overhauled is separated from the module guide rail and is located on the first overhauling guide rail for overhauling, and at the moment, the upper steel belt and the lower steel belt are both located in a first gap in the overhauling bracket.

Compared with the prior art, the utility model has the following beneficial effects:

1. the utility model has simple structure and convenient operation, adopts the technical means of arranging a plurality of processing modules in parallel, realizes the modularization customization of processing equipment, can customize various processing modules according to the product technology, and can conveniently replace various processing modules, thereby being suitable for the requirements of various different production technologies.

2. The utility model adopts the technical means that the overhauling bracket can drive the processing module to be overhauled to be separated from the module guide rail, and can conveniently overhauls the parts in the narrow space inside the processing module to be overhauled on the premise of not cutting off the steel belt.

Drawings

Other features, objects and advantages of the present utility model will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of the structure of the present utility model;

fig. 2 is a schematic side view of the maintenance mechanism and the processing module in the present utility model.

The figure shows:

lower steel band 1 processing module 9

First service guide rail 2 service bracket 10

Oil cylinder 11 of upper steel belt 3

First driven roller 12 of upper longitudinal beam 4

First frame 13 of transverse beam 5

First drive roll 6 second service rail 14

Second frame 15 of vertical beam 7

Lower longitudinal beam 8

Detailed Description

The present utility model will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the present utility model, but are not intended to limit the utility model in any way. It should be noted that variations and modifications could be made by those skilled in the art without departing from the inventive concept. These are all within the scope of the present utility model.

The utility model discloses a modularized double-steel-belt continuous press, which realizes the modularized customization of processing equipment by adopting a technical means that a plurality of processing modules 9 are arranged in parallel and customizable, can customize various different processing modules 9 according to the product technology, and can conveniently overhaul and replace various processing modules 10, thereby adapting to the requirements of various different production technologies.

According to the modularized double-steel-belt continuous press provided by the utility model, as shown in fig. 1, the modularized double-steel-belt continuous press comprises a driving mechanism, a driven mechanism, an upper steel belt 3, a lower steel belt 1, a connecting frame and a plurality of processing modules 9, wherein the processing modules 9 can be customized according to the product technology; the processing modules 9 are arranged in the connecting frame in parallel along the length direction of the connecting frame and are detachably connected with the connecting frame, the adjacent processing modules 9 are not connected or detachably connected, the driving mechanism is arranged at one end of the connecting frame and comprises an upper driving mechanism and a lower driving mechanism, the driven mechanism is arranged at the other end of the connecting frame and comprises an upper driven mechanism and a lower driven mechanism; preferably, the processing module 9 includes a heating module, a pressurizing module, and a heating and pressurizing module, and the specific structure and the sequence can be customized according to the process of the product.

The connecting frame comprises an upper longitudinal beam 4, a transverse beam 5, a vertical beam 7 and a lower longitudinal beam 8; the upper longitudinal beams 4 and the lower longitudinal beams 8 are arranged in parallel, a plurality of upper longitudinal beams 4 are connected with each other through transverse beams 5, the upper longitudinal beams 4 and the lower longitudinal beams 8 are connected with each other through vertical beams 7, a plurality of processing modules 9 are arranged in parallel along the length direction of the upper longitudinal beams 4, and the upper longitudinal beams 4 and the lower longitudinal beams 8 are detachably connected with the processing modules 9. Preferably, the structural beams forming the connecting frame are connected through M12 bolts.

The processing module 9 comprises an upper processing module and a lower processing module, the upper steel belt 3 is sleeved outside the upper driving mechanism, the upper processing module and the upper driven mechanism, and the lower steel belt 1 is sleeved outside the lower driving mechanism, the lower processing module and the lower driven mechanism; the upper driving mechanism comprises a second driving roller, and the lower driving mechanism comprises a first driving roller 6; the second driving roller can drive the upper steel belt 3 to run through rotation, the first driving roller 6 can drive the lower steel belt 1 to run through rotation, and the rotation directions of the first driving roller 6 and the second driving roller are opposite. The driving mechanism further comprises a second rack 15, and the second rack 15 is fixedly arranged at one end of the connecting frame; the first driving roller 6 is arranged at the lower part of the second frame 15, and the second driving roller is arranged at the upper part of the second frame 15.

The upper driven mechanism comprises a second driven roller, and the lower driven mechanism comprises a first driven roller 12; the second driven roller can rotate under the drive of the upper steel belt 3, the first driven roller 12 can rotate under the drive of the lower steel belt 1, and the rotation direction between the second driven roller and the first driven roller 12 is opposite. The driven mechanism further comprises a first rack 13, and the first rack 13 is fixedly arranged at the other end of the connecting frame; the first driven roller 12 is arranged at the lower part of the first frame 13, and the second driven roller is arranged at the upper part of the first frame 13. An oil cylinder 11 for tensioning the upper steel belt 3 and the lower steel belt 1 is further arranged in the first frame 13 of the driven mechanism, the oil cylinder 11 is connected with the upper steel belt 3 and the lower steel belt 1, and when the equipment starts to operate, the oil cylinder 11 is started to tension the steel belts.

A feeding hole is formed between the upper driving mechanism and the lower driving mechanism, and a discharging hole is formed between the upper driven mechanism and the lower driven mechanism; or a discharge hole is formed between the upper driving mechanism and the lower driving mechanism, and a feed inlet is formed between the upper driven mechanism and the lower driven mechanism; the driving mechanism can drive the upper steel belt 3 and the lower steel belt 1 to operate, so that materials to be processed are input into the processing module 9 from the feed inlet, processed materials are output from the discharge outlet, and the operation directions of the upper steel belt 3 and the lower steel belt 1 are opposite.

Preferably, a feeding port is formed between the second driven roller and the first driven roller 12, and in a longitudinal projection, the first driven roller 12 is far away from the processing module 9 than the second driven roller, and the lower steel belt 1 on the first driven roller 12 forms a feeding platform, so that materials to be processed conveniently enter the processing module 9;

or a feeding hole is formed between the first driving roller 6 and the second driving roller, on the longitudinal projection, the first driving roller 6 is far away from the processing module 9 than the second driving roller, and the lower steel belt 1 on the first driving roller 6 forms a feeding platform, so that materials to be processed conveniently enter the processing module 9.

In order to facilitate the replacement and maintenance of the processing module 9, as shown in fig. 2, the modular double-steel-belt continuous press further comprises a maintenance mechanism, wherein the maintenance mechanism comprises a first maintenance guide rail 2, a maintenance support 10 and a second maintenance guide rail 14, and a module guide rail perpendicular to the material transportation direction is arranged at the bottom of the processing module 9;

when the processing module 9 needs to be overhauled, the first overhauling guide rail 2 and the second overhauling guide rail 14 are respectively connected with two ends of the module guide rail and are arranged in parallel with the module guide rail, and the overhauling bracket 10 is arranged on the second overhauling guide rail 14; the end part of the overhaul support 10 is fixedly connected with the processing module 9 to be overhauled through a bolt of M12, a first gap is formed in the end part of the overhaul support 10, and the overhaul support 10 can drive the processing module 9 to be overhauled to move from an initial position to an overhaul position;

when the processing module 9 to be overhauled is positioned at the initial position, the processing module 9 to be overhauled is positioned on the module guide rail, and at the moment, the upper steel belt 3 and the lower steel belt 1 are positioned in the processing module 9 to be overhauled; when the processing module 9 to be overhauled is located at the overhauling position, the processing module 9 to be overhauled is separated from the module guide rail and is located on the first overhauling guide rail 2 for overhauling, and at the moment, the upper steel belt 3 and the lower steel belt 1 are located in the first gap in the overhauling bracket 10. When the service bracket 10 reaches a maximum displacement. The entire tooling module 9 can be pushed out of the range of the connecting frame.

In the description of the present application, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, merely to facilitate description of the present application and simplify the description, and do not indicate or imply that the devices or elements being referred to must have a specific orientation, be configured and operated in a specific orientation, and are not to be construed as limiting the present application.

The foregoing describes specific embodiments of the present utility model. It is to be understood that the utility model is not limited to the particular embodiments described above, and that various changes or modifications may be made by those skilled in the art within the scope of the appended claims without affecting the spirit of the utility model. The embodiments of the present application and features in the embodiments may be combined with each other arbitrarily without conflict.

Claims (10)

1. The modularized double-steel-belt continuous press is characterized by comprising a driving mechanism, a driven mechanism, an upper steel belt (3), a lower steel belt (1), a connecting frame and a plurality of processing modules (9);

the processing modules (9) are arranged in the connecting frame in parallel along the length direction of the connecting frame and are detachably connected with the connecting frame, adjacent processing modules (9) are not connected or are detachably connected, the driving mechanism is arranged at one end of the connecting frame and comprises an upper driving mechanism and a lower driving mechanism, the driven mechanism is arranged at the other end of the connecting frame and comprises an upper driven mechanism and a lower driven mechanism;

the processing module (9) comprises an upper processing module and a lower processing module, the upper steel belt (3) is sleeved outside the upper driving mechanism, the upper processing module and the upper driven mechanism, and the lower steel belt (1) is sleeved outside the lower driving mechanism, the lower processing module and the lower driven mechanism;

a feeding hole is formed between the upper driving mechanism and the lower driving mechanism, and a discharging hole is formed between the upper driven mechanism and the lower driven mechanism; or a discharge hole is formed between the upper driving mechanism and the lower driving mechanism, and a feed inlet is formed between the upper driven mechanism and the lower driven mechanism;

the driving mechanism can drive the upper steel belt (3) and the lower steel belt (1) to operate, so that materials to be processed are input into the processing module (9) from the feed inlet, processed materials are output from the discharge outlet, and the operation directions of the upper steel belt (3) and the lower steel belt (1) are opposite.

2. The modular twin-steel strip continuous press as claimed in claim 1, characterised in that the upper driving mechanism comprises a second driving roller and the lower driving mechanism comprises a first driving roller (6);

the second driving roller can drive the upper steel belt (3) to run through rotation, the first driving roller (6) can drive the lower steel belt (1) to run through rotation, and the rotation directions of the first driving roller (6) and the second driving roller are opposite.

3. The modular twin steel belt continuous press as claimed in claim 2, characterized in that the driving mechanism further comprises a second frame (15), the second frame (15) being fixedly arranged at one end of the connecting frame;

the first driving roller (6) is arranged at the lower part of the second frame (15), and the second driving roller is arranged at the upper part of the second frame (15).

4. The modular twin steel belt continuous press as claimed in claim 1 wherein the upper driven mechanism comprises a second driven roller and the lower driven mechanism comprises a first driven roller (12);

the second driven roller can rotate under the drive of the upper steel belt (3), the first driven roller (12) can rotate under the drive of the lower steel belt (1), and the rotation direction between the second driven roller and the first driven roller (12) is opposite.

5. The modular twin steel belt continuous press as claimed in claim 4, wherein the driven mechanism further comprises a first frame (13), the first frame (13) being fixedly arranged at the other end of the connection frame;

the first driven roller (12) is arranged at the lower part of the first frame (13), and the second driven roller is arranged at the upper part of the first frame (13).

6. The modular twin steel belt continuous press as claimed in claim 4, characterised in that a feed opening is formed between the second driven roller and the first driven roller (12), the first driven roller (12) being further away from the processing module (9) in longitudinal projection than the second driven roller.

7. The modular twin-belt continuous press according to claim 1, further comprising a cylinder (11) for tensioning the upper belt (3) and the lower belt (1), the cylinder (11) being arranged inside the driven mechanism and connecting the upper belt (3) and the lower belt (1).

8. The modular twin steel belt continuous press as claimed in claim 1, characterised in that the processing module (9) comprises a heating module, a pressurizing module and a heating pressurizing module.

9. The modular twin steel belt continuous press according to claim 1, characterized in that the connecting frame comprises an upper longitudinal beam (4), a transverse beam (5), a vertical beam (7) and a lower longitudinal beam (8);

the upper longitudinal beams (4) and the lower longitudinal beams (8) are arranged in parallel, a plurality of upper longitudinal beams (4) are connected with each other through transverse beams (5), the upper longitudinal beams (4) and the lower longitudinal beams (8) are connected with each other through vertical beams (7), and a plurality of processing modules (9) are arranged in parallel along the length direction of the upper longitudinal beams (4);

the upper longitudinal beam (4) and the lower longitudinal beam (8) are detachably connected with the processing module (9).

10. The modular double steel belt continuous press according to claim 1, further comprising an inspection mechanism comprising a first inspection rail (2), an inspection support (10) and a second inspection rail (14), the bottom of the processing module (9) being provided with a module rail perpendicular to the material transport direction;

when the processing module (9) needs to be overhauled, the first overhauling guide rail (2) and the second overhauling guide rail (14) are respectively connected with two ends of the module guide rail and are arranged in parallel with the module guide rail, and the overhauling bracket (10) is arranged on the second overhauling guide rail (14);

the end part of the overhaul support (10) is fixedly connected with the processing module (9) to be overhauled, a first gap is formed in the end part of the overhaul support (10), and the overhaul support (10) can drive the processing module (9) to be overhauled to move from an initial position to an overhaul position;

when the processing module (9) to be overhauled is positioned at the initial position, the processing module (9) to be overhauled is positioned on the module guide rail, and at the moment, the upper steel belt (3) and the lower steel belt (1) are positioned in the processing module (9) to be overhauled;

when the processing module (9) to be overhauled is located at the overhauling position, the processing module (9) to be overhauled is separated from the module guide rail and is located on the first overhauling guide rail (2) to be overhauled, and at the moment, the upper steel belt (3) and the lower steel belt (1) are both located in a first gap in the overhauling bracket (10).

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