CN117000816A - Multi-split high-strength sheet straightener distribution box and straightener - Google Patents

Abstract

The application provides a distribution box of a multi-split high-strength sheet straightener and the straightener, and relates to the technical field of straighteners, the distribution box comprises a box body, an input end is arranged at the front side of the box body, an output end is arranged at the rear side of the box body, and the output end comprises a first output shaft group and a second output shaft group; the inside of the box body is also divided into a first flow distribution area and a second flow distribution area, a third main flow distribution shaft, a fourth main flow distribution shaft and a fifth main flow distribution shaft are arranged on the upper layer of the first flow distribution area in an equidistant rotation mode, and a first main flow distribution shaft and a second main flow distribution shaft are symmetrically arranged on the lower layer of the first flow distribution area. The application provides a gear box meeting the requirements of a transmission structure form and torque, which can divide the torque in advance through a plurality of layers of divided gears, form a required transmission mode, meet the transmission relation, ensure that the gear box is connected with a working machine through an imported small-angle offset coupling, further meet the working requirements, and finally achieve the multiple requirements of the torque, the size and the transmission mode.

Description

Multi-split high-strength sheet straightener distribution box and straightener

Technical Field

The application relates to the technical field of straightening machines, in particular to a distribution box of a multi-split high-strength sheet straightening machine and the straightening machine.

Background

As the quality and precision requirements of steel become higher, some plates, sections and pipes must be subjected to a straightening process to meet the requirements of users, and the straightening quality has become an important standard for measuring the competitiveness of products. In this context, straightening techniques are rapidly evolving and are increasingly being used.

The distribution box of the straightening machine is widely applied to the subsequent finishing process of the plate production, but the traditional straightening machine has few rollers and large roller spacing, and the composition and transmission form of the traditional straightening machine can not meet the requirements of small roller spacing, large transmission torque and multi-roller output.

Disclosure of Invention

The application aims to provide a distribution box of a multi-split high-strength sheet straightener and the straightener, which can meet the requirements of small roller space, large transmission torque and multi-roller output.

Embodiments of the present application are implemented as follows:

the application provides a distributing box of a multi-split high-strength sheet straightener, which comprises the following components:

the box body is provided with an input end at the front side of the input end, an output end is arranged at the rear side of the box body, and the output end comprises a first output shaft group and a second output shaft group;

the inner part of the box body is also divided into a first diversion area and a second diversion area, wherein a third main diversion shaft, a fourth main diversion shaft and a fifth main diversion shaft are arranged on the upper layer of the first diversion area in an equidistant rotation mode, a first main diversion shaft and a second main diversion shaft are symmetrically arranged on the lower layer of the first diversion area, a seventh secondary diversion shaft, an eighth secondary diversion shaft, a ninth secondary diversion shaft and a tenth secondary diversion shaft are respectively arranged on the upper layer of the second diversion area in a rotation mode, and a first secondary diversion shaft, a second secondary diversion shaft, a third secondary diversion shaft, a fourth secondary diversion shaft, a fifth secondary diversion shaft and a sixth secondary diversion shaft are respectively arranged on the lower layer of the second diversion area in a rotation mode;

the upper layer of the main split shaft III, the main split shaft IV and the main split shaft V are correspondingly in transmission fit with the lower layer of the main split shaft I and the main split shaft II, and the upper layer of the secondary split shaft seven, the secondary split shaft eight and the secondary split shaft nine and the secondary split shaft ten are correspondingly in transmission fit with the lower layer of the secondary split shaft I, the secondary split shaft II, the secondary split shaft III, the secondary split shaft IV and the secondary split shaft five and the secondary split shaft six.

In an optional technical scheme of the embodiment, a first main split gear is fixedly arranged in a first split area, two first auxiliary split gears are fixedly arranged in a second split area, a third main split gear and a fourth main split gear are fixedly arranged in a first split area respectively, and two third auxiliary split gears and two fourth auxiliary split gears are fixedly arranged in a second split area;

the first main split gear is meshed with the third main split gear and the fourth main split gear.

In an optional technical scheme of this embodiment, the fifth main split gear is fixedly arranged in the first split area, two fifth auxiliary split gears are fixedly arranged in the second split area, the second main split gear is fixedly arranged in the first split area, two second auxiliary split gears are fixedly arranged in the second split area, and the second main split gear is meshed with the fifth main split gear.

In an optional technical scheme of this embodiment, a first secondary shunt gear and a second secondary shunt gear are fixedly arranged on the first secondary shunt shaft and the second secondary shunt shaft respectively, and the two third secondary shunt gears are meshed with the first secondary shunt gear and the second secondary shunt gear respectively.

In an optional technical scheme of this embodiment, a third sub-split gear and a fourth sub-split gear are fixedly connected to the third sub-split shaft and the fourth sub-split shaft respectively, and the two fourth sub-split gears are meshed with the third sub-split gear and the fourth sub-split gear respectively.

In an optional technical scheme of this embodiment, a fifth secondary split gear and a sixth secondary split gear are fixedly connected to the fifth secondary split shaft and the sixth secondary split shaft respectively, and the two fifth secondary split gears are meshed with the fifth secondary split gear and the sixth secondary split gear respectively.

In an optional technical scheme of this embodiment, a secondary split gear seven and a secondary split gear eight are fixedly connected to the secondary split shaft seven and the secondary split shaft eight respectively, and the two secondary split gears are meshed with the secondary split gear seven and the secondary split gear eight respectively.

In an optional technical scheme of this embodiment, a secondary shunt gear nine and a secondary shunt gear ten are fixedly connected to the secondary shunt shaft nine and the secondary shunt shaft ten respectively, and two secondary shunt gears are meshed with the secondary shunt gear nine and the secondary shunt gear ten respectively.

The embodiment also provides a straightener, which comprises the distribution box of the multi-split high-strength sheet straightener.

In an alternative technical scheme of the embodiment, the straightener further comprises a motor assembly, and the motor assembly is in transmission connection with the input end.

The embodiment of the application has the beneficial effects that:

the application provides a gear box meeting the requirements of a transmission structure form and torque, which can divide the torque in advance through a plurality of layers of divided gears, form a required transmission mode, meet the transmission relation, ensure that the gear box is connected with a working machine through an imported small-angle offset coupling, further meet the working requirements, and finally achieve the multiple requirements of the torque, the size and the transmission mode.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall top view structure of a distribution box of a multi-split high-strength sheet straightener according to the present application;

FIG. 2 is a schematic diagram showing the front view of a distribution box of a multi-split high-strength sheet straightener according to the present application;

FIG. 3 is a schematic view of the cross-sectional B-B structure of FIG. 2;

fig. 4 is a schematic view of the cross-section A-A in fig. 2.

Icon:

100-box body; 101-an input; 102-an output; 102 A-A first output shaft set; 102 b-a second output shaft set; 200-a first split area; 201-primary shunt shaft one; 201 A-A first main split gear; 201 b-a first slave split gear; 202-a second main split shaft; 202 A-A second main split gear; 202 b-a second slave split gear; 203-a main split shaft three; 203 A-A third main split gear; 203 b-a third slave split gear; 204-a main split shaft IV; 204 A-A fourth main split gear; 204 b-a fourth slave split gear; 205-a main split shaft five; 205 A-A fifth main split gear; 205 b-a fifth slave split gear; 300-a second split area; 301-splitting the first shaft; 301 A-A first split gear; 302-secondary split shaft II; 302 a-secondary split gear two; 303-a third split shaft; 303 A-A third split gear; 304-a secondary split shaft IV; 304 A-A fourth split gear; 305-a fifth split shaft; 305 a-fifth split gear; 306-a secondary split shaft six; 306 A-A secondary split gear six; 307-split shaft seven; 307 A-A secondary split gear seven; 308-a secondary split shaft eight; 308a—a secondary split gear eight; 309-nine split axes; 309 A-A secondary split gear nine; 310-times of split shaft ten; 310 a-secondary split gear ten.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present application more apparent, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments of the present application. The components of the embodiments of the present application generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the application, as presented in the figures, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present application, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships conventionally put in use of the inventive product, are merely for convenience of describing the present application and simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal," "vertical," and the like do not denote a requirement that the component be absolutely horizontal or overhang, but rather may be slightly inclined. As "horizontal" merely means that its direction is more horizontal than "vertical", and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present application, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

Referring to FIGS. 1-4, for one embodiment of the present application, there is provided a distributor box for a multi-split high strength sheet straightener, the distributor box comprising: the box 100, the front side of box 100 is provided with input 101, and the rear side of box 100 is provided with output 102, includes first output shaft group 102a and second output shaft group 102b on the output 102, and first output shaft group 102a and the output shaft of second output shaft group 102b are crisscross to be distributed, with the primary and secondary reposition of redundant personnel axle one-to-one in the drawing, and the inside of box 100 still separates first reposition of redundant personnel district 200 and second reposition of redundant personnel district 300. The first output shaft set 102a is correspondingly matched with the plurality of secondary split shafts, and the second output shaft set 102b is correspondingly matched with the plurality of main split shafts, so that torque output is realized.

The upper layer of the first split area 200 is provided with a main split shaft three 203, a main split shaft four 204 and a main split shaft five 205 in an equidistant rotation mode, the lower layer of the first split area 200 is symmetrically provided with a main split shaft one 201 and a main split shaft two 202, the upper layer of the second split area 300 is respectively provided with a sub split shaft seven 307, a sub split shaft eight 308, a sub split shaft nine 309 and a sub split shaft ten 310 in a rotation mode, the lower layer is respectively provided with a sub split shaft one 301, a sub split shaft two 302, a sub split shaft three 303, a sub split shaft four 304 and a sub split shaft five 305 in a rotation mode, and a sub split shaft six 306 in a rotation mode, the main split shaft three 203, the main split shaft four 204 and the main split shaft five 205 in a rotation mode are correspondingly in transmission mode with the main split shaft one 201 and the main split shaft two 202 in the lower layer, and the sub split shaft seven 307, the sub split shaft eight 308, the sub split shaft nine 309 and the sub split shaft ten 310 in the lower layer are correspondingly in transmission mode with the sub split shaft one 301, the sub split shaft two 302, the sub split shaft three and the sub split shaft 306 in the rotation mode and the sub split shaft 304 in the lower layer are correspondingly in transmission mode.

The specific matching relationship is that a first main split gear 201a is fixedly arranged in the first split area 200, two first auxiliary split gears 201b are fixedly arranged in the second split area 300, a third main split gear 203a and a fourth main split gear 204a are fixedly arranged in the first split area 200, two third auxiliary split gears 203b and two fourth auxiliary split gears 204b are fixedly arranged in the second split area 300, and the first main split gear 201a is meshed with the third main split gear 203a and the fourth main split gear 204 a. That is to say, the transmission of the third main split shaft 203 and the fourth main split shaft 204 on two sides can be driven by the input of the first main split shaft 201, the fifth main split gear 205a is fixedly arranged in the area of the first split area 200, the two fifth auxiliary split gears 205b are fixedly arranged in the area of the second split area 300, the second main split gear 202a is fixedly arranged in the area of the first split area 200, the two second auxiliary split gears 202b are fixedly arranged in the area of the second split area 300, the second main split gear 202a is meshed with the fifth main split gear 205a, and the synchronous driving of the fifth main split shaft 205 is completed by the input access of the second main split shaft 202.

The first sub-split shaft 301 and the second sub-split shaft 302 are respectively fixedly provided with a first sub-split gear 301a and a second sub-split gear 302a, the two third sub-split gears 203b are respectively meshed with the first sub-split gear 301a and the second sub-split gear 302a, that is to say, the rotation output of the first sub-split shaft 301 and the second sub-split shaft 302 is synchronously driven through the single third main split shaft 203, the third sub-split shaft 303 and the fourth sub-split shaft 304 are respectively fixedly connected with a third sub-split gear 303a and a fourth sub-split gear 304a, and the two fourth sub-split gears 204b are respectively meshed with the third sub-split gear 303a and the fourth sub-split gear 304 a. That is to say, the rotation output of the third sub-split shaft 303 and the fourth sub-split shaft 304 is synchronously driven by the fourth main split shaft 204, the fifth sub-split shaft 305 and the sixth sub-split shaft 306 are respectively and fixedly connected with the fifth sub-split gear 305a and the sixth sub-split gear 306a, and the fifth sub-split gears 205b are respectively meshed with the fifth sub-split gear 305a and the sixth sub-split gear 306 a. That is to say, the rotation output of the secondary split shaft five 305 and the secondary split shaft six 306 is synchronously driven by the single primary split shaft five 205.

Specifically, the secondary split shaft seven 307 and the secondary split shaft eight 308 are fixedly connected with a secondary split gear seven 307a and a secondary split gear eight 308a, respectively, and the two first secondary split gears 201b are meshed with the secondary split gear seven 307a and the secondary split gear eight 308a, respectively. That is, the portion of the first main split shaft 201 extending to the area of the second split area 300 may further drive the rotation output of the seventh sub split shaft 307 and the eighth sub split shaft 308, where the ninth sub split shaft 309 and the tenth sub split shaft 310 are respectively and fixedly connected with the ninth sub split gear 309a and the tenth sub split gear 310a, and the two second sub split gears 202b are respectively meshed with the ninth sub split gear 309a and the tenth sub split gear 310 a. That is, the part of the second main split shaft 202 extending to the second split area 300 can drive the rotation output of the ninth sub split shaft 309 and the tenth sub split shaft 310.

According to the application, through the input connection of the first main split shaft 201 and the second main split shaft 202, the synchronous transmission of the third main split shaft 203, the fourth main split shaft 204 and the fifth main split shaft 205 is realized under the transmission fit of the gear sets in the first split region 200, and the transmission fit of the gear sets in the second split region 300 is the same, so that the first main split shaft 201, the second main split shaft 202, the third main split shaft 203, the fourth main split shaft 204 and the fifth main split shaft 205 are connected into the second split region 300 to serve as driving parts, the power output of the first sub split shaft 301, the second sub split shaft 302, the third sub split shaft 303, the fourth sub split shaft 304, the fifth sub shaft 305, the sixth sub shaft 306, the seventh sub split shaft 307, the eighth sub split shaft 308, the ninth sub split shaft 309 and the tenth sub split shaft 310 is realized, namely the gearbox which meets the transmission structure form and the torque requirement is provided by the multi-layer split gears, the required transmission form is realized, the required transmission form is met, the transmission form is ensured, the transmission form is met, the transmission form is realized, the transmission form is also is met, the requirement is met, the working form is met, the requirement is met, and the working form is met, and the requirement and the transmission form is realized through the small size and the working form is realized.

The embodiment also provides a straightener, which comprises the distribution box of the multi-split high-strength sheet straightener and a motor assembly, wherein the motor assembly is connected with the box body, and an output shaft of the motor assembly is in transmission connection with an input end 101 of the box body, so that input torque is provided.

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

Claims (10)

1. A multi-split high strength sheet straightener distributor box, comprising:

the box body (100), the front side of the box body (100) is provided with an input end (101), the rear side of the box body (100) is provided with an output end (102), and the output end (102) comprises a first output shaft group (102 a) and a second output shaft group (102 b);

the inside of the box body (100) is further divided into a first split-flow area (200) and a second split-flow area (300), a third main split-flow axis (203), a fourth main split-flow axis (204) and a fifth main split-flow axis (205) are arranged on the upper layer of the first split-flow area (200) in an equidistant rotating mode, a first main split-flow axis (201) and a second main split-flow axis (202) are symmetrically arranged on the lower layer of the first split-flow area (200), a seventh sub split-flow axis (307), an eighth sub split-flow axis (308), a ninth sub split-flow axis (309) and a tenth sub split-flow axis (310) are respectively arranged on the upper layer of the second split-flow area (300) in a rotating mode, and a first sub split-flow axis (301), a second sub split-flow axis (302), a third sub-flow axis (303), a fourth sub-flow axis (304) and a fifth sub-flow axis (305) and a sixth sub-flow axis (306) are respectively arranged on the lower layer in a rotating mode;

the main split shaft III (203), the main split shaft IV (204), the main split shaft V (205) on the upper layer are correspondingly in transmission fit with the main split shaft I (201) and the main split shaft II (202) on the lower layer, the sub split shaft seven (307), the sub split shaft eight (308), the sub split shaft nine (309) and the sub split shaft ten (310) on the upper layer are correspondingly in transmission fit with the sub split shaft I (301), the sub split shaft II (302), the sub split shaft III (303), the sub split shaft IV (304), the sub split shaft V (305) and the sub split shaft VI (306) on the lower layer.

2. The distributor box of the multi-split high-strength sheet straightener as claimed in claim 1, wherein:

a first main split gear (201 a) is fixedly arranged in the first split area (200), two first auxiliary split gears (201 b) are fixedly arranged in the second split area (300), a third main split gear (203 a) and a fourth main split gear (204 a) are fixedly arranged in the first split area (200), and two third auxiliary split gears (203 b) and two fourth auxiliary split gears (204 b) are fixedly arranged in the second split area (300);

the first main split gear (201 a) is meshed with a third main split gear (203 a) and a fourth main split gear (204 a).

3. The distributor box of the multi-split high-strength sheet straightener as claimed in claim 2, wherein:

the five (205) main split shaft is located in the first split area (200) and is fixedly provided with a fifth main split gear (205 a), the two fifth auxiliary split gears (205 b) are located in the second split area (300), the two main split shafts (202) are located in the first split area (200) and are fixedly provided with second main split gears (202 a), the two second auxiliary split gears (202 b) are located in the second split area (300), and the second main split gears (202 a) are meshed with the fifth main split gears (205 a).

4. A multi-split high strength sheet straightener distributor box as claimed in claim 3, wherein:

the first secondary shunt shaft (301) and the second secondary shunt shaft (302) are respectively fixedly provided with a first secondary shunt gear (301 a) and a second secondary shunt gear (302 a), and the two third secondary shunt gears (203 b) are respectively meshed with the first secondary shunt gear (301 a) and the second secondary shunt gear (302 a).

5. The distribution box of the multi-split high-strength sheet straightener, as claimed in claim 4, is characterized in that:

and the third secondary shunt shaft (303) and the fourth secondary shunt shaft (304) are respectively and fixedly connected with a third secondary shunt gear (303 a) and a fourth secondary shunt gear (304 a), and the two fourth secondary shunt gears (204 b) are respectively meshed with the third secondary shunt gear (303 a) and the fourth secondary shunt gear (304 a).

6. The distribution box of the multi-split high-strength sheet straightener, as claimed in claim 5, is characterized in that:

and a fifth secondary split shaft (305) and a sixth secondary split shaft (306) are respectively and fixedly connected with a fifth secondary split gear (305 a) and a sixth secondary split gear (306 a), and the two fifth secondary split gears (205 b) are respectively meshed with the fifth secondary split gear (305 a) and the sixth secondary split gear (306 a).

7. The distribution box of the multi-split high-strength sheet straightener, as claimed in claim 6, is characterized in that:

the secondary split shaft seven (307) and the secondary split shaft eight (308) are respectively and fixedly connected with a secondary split gear seven (307 a) and a secondary split gear eight (308 a), and the two first secondary split gears (201 b) are respectively meshed with the secondary split gear seven (307 a) and the secondary split gear eight (308 a).

8. The distribution box of the multi-split high-strength sheet straightener, as claimed in claim 7, is characterized in that:

and the secondary split shaft nine (309) and the secondary split shaft ten (310) are respectively and fixedly connected with a secondary split gear nine (309 a) and a secondary split gear ten (310 a), and the two secondary split gears (202 b) are respectively meshed with the secondary split gear nine (309 a) and the secondary split gear ten (310 a).

9. A straightener, characterized in that the straightener comprises:

a multi-split high strength sheet straightener distributor box as claimed in any one of claims 1 to 8.

10. The leveler according to claim 9, wherein:

the straightening machine further comprises a motor assembly, and the motor assembly is in transmission connection with the input end (101).