1. Technical Field
The present invention relates to the technical field of rolling equipment for fabric crafts and paper crafts, and more particularly to a decorative material rolling mill having an adjustable roll gap.
2. Related Art
Currently, rolling mills having fixed roll spaces are used home and abroad for fabric crafts and paper crafts. To use die sheets of different thicknesses for shearing and use knurling dies of different thicknesses for knurling, rolling plates of different thicknesses require to be equipped to meet sizes specified by roll spaces of rolling mills, and rolling plates of corresponding thicknesses require to be replaced, which increases the complexity of the process. In addition, rolling mills having fixed roll spaces cannot accommodate thickness differences among die sheets and knurling dies from different manufacturers precisely, making operations inconvenient.
The technical problem to be solved by the present invention is to provide a rolling mill having an adjustable roll gap through manual shifting and a rolling mill having an automatically adjustable roll gap using a thickness measuring probe for existing deficiencies in rolling mills for existing handicrafts such as fabric crafts and paper crafts.
The technical problem to be solved by the present invention is solved through the following technical solutions:
A decorative material rolling mill having an adjustable roll gap includes:
The further includes: a rolling gap adjustment mechanism for driving the upper roll or the lower roll to move vertically along the left frame and the right frame, thereby adjusting a rolling gap between the upper roll and the lower roll according to the thickness of a shearing die.
In a preferred embodiment of the present invention, the two ends of the upper roll or the lower roll are disposed on the left frame and the right frame through sliding blocks, and the rolling gap adjustment mechanism drives the sliding blocks to move vertically along the left frame and the right frame.
In a preferred embodiment of the present invention, the driving mechanism includes: a driving small gear axially disposed on the left frame or the right frame through a driving handle shaft, a large gear located at the same side as the driving small gear and axially disposed on a shaft end at one side of the upper roll or the lower roll, and a transmission gear set axially disposed on a shaft end at a random side of the upper roll and the lower roll; and a crank handle is arranged on the driving handle shaft.
In a preferred embodiment of the present invention, the rolling gap adjustment mechanism includes:
In a preferred embodiment of the present invention, a guide rail groove is arranged on the guide rail plate along the length direction of the guide rail plate; a sliding key and a pair of trench plates are arranged inside the guide rail groove, the sliding key is connected to the dual-joint slope block, the pair of trench plates is arranged at two sides of the sliding key; a radial positioning hole is provided on the sliding key, a pair of positioning steel balls and a positioning spring are arranged inside the radial positioning hole, the positioning spring is arranged between the pair of steel balls; several positioning trenches or positioning holes are provided at an interval on one trench plate, and one positioning steel ball is pressed inside one random positioning trench or positioning hole under the effect of the positioning spring, so as to position the dual-joint slope block.
In a preferred embodiment of the present invention, horizontal stops are disposed at middle portions of the left frame and the right frame, and sliding block reset springs are disposed between bottom surfaces or top surfaces of the sliding blocks and the horizontal stops.
In a preferred embodiment of the present invention, the active slopes and the passive slopes are both stepped slopes.
In a preferred embodiment of the present invention, the active slope and the passive slopes connected in a slideable manner by adopting a structure of a T-shaped groove and a T-shaped guide rail being inserted to each other.
In a preferred embodiment of the present invention, a screw hole is provided at the left end or the right end of the dual joint slope block, a bolt support portion is disposed on the left frame or the right frame, a radially rotatable but axially-constrained screw rod is arranged on the bolt support portion, and the screw rod is screwed inside the screw hole.
In a preferred embodiment of the present invention, the rolling gap adjustment mechanism includes:
In a preferred embodiment of the present invention, the rolling gap adjustment mechanism includes:
In a preferred embodiment of the present invention, the rolling gap adjustment mechanism includes:
In a preferred embodiment of the present invention, the left frame is formed of a left front support and a left rear support, and right frame is formed of a right front support and a right rear support.
In a preferred implementation of the present invention, the left front support, the left rear support, the right front support, and the right rear support are formed by adopting a casting forming method along an aperture.
By adopting the foregoing technical solutions, the present invention uses a rolling gap adjustment mechanism to adjust a rolling gap between an upper roll and a lower roll, thereby accommodating thickness differences among die sheets, upper rolling plates, and lower rolling plates from different manufacturers. Various rolling gap adjustment mechanisms disclosed by the present invention are simple in structure and convenient to use.
The present disclosure will become more fully understood from the detailed description given herein below for illustration only, and thus are not limitative of the present disclosure, and wherein:
The present invention is further described below with reference to the accompanying drawings and specific implementation manners.
Refer to
Bottom portions of the left frame 100 and the right frame 100a are connected through a lower connecting plate 130. In connecting, the lower connecting plate 130 further connects the left front support 110 and the left rear support 120 and connects the right front support 110a and the right rear support 120a through a fastening bolt.
Top portions of the left frame 100 and the right frame 100a are connected through a guide rail plate 140. In connecting, the guide rail plate 140 further connects the left front support 110 and the left rear support 120 and connects the right front support 110a and the right rear support 120a through a fastening bolt.
When being connected adopting the foregoing manner, the left frame 100, the right frame 100a, the lower connecting plate 130, and the guide rail plate 140 form a rectangular frame.
The decorative material rolling mill having an adjustable roll gap depends on a pair of rolls to work. The pair of rolls includes an upper roll 210 and a lower roll 220. The lower roll 220 is supported on lower portions of the left frame 100 and the right frame 100a through a pair of ball bearings 221, 221a, that is, supported on lower portions of the left front support 110 and the left rear support 120 and lower portions of the right front support 110a and the right rear support 120a.
A left horizontal stop 150 is connected between middle portions of the left front support 110 and the left rear support 120. A right horizontal stop 150a is connected between middle portions of the right front support 110a and the right rear support 120a. A sliding cavity 160 for a sliding block to slide vertically is formed in the space located above the horizontal stop 150 of the left front support 110 and the left rear support 120. A sliding cavity 160a for a sliding block to slide vertically is formed in the space located above the horizontal stop 150a of the right front support 110a and the right rear support 120a.
Sliding blocks 230, 230a are placed inside the sliding cavities 160, 160a, respectively. Sliding block reset springs 240, 240a are disposed between bottom surfaces of sliding blocks 230 and 230a and the horizontal stops 150, 150a. Top surfaces of the sliding blocks 230, 230a are passive slopes 231, 231a with the same inclined angle and parallel to each other.
Two ends of the upper roll 210 are supported on the sliding blocks 230, 230a through needle roller bearings 211, 211a, respectively.
The rotation of the upper roll 210 and the lower roll 220 depends on a driving mechanism. The driving mechanism includes a small gear 310, a large gear 320, an active gear 330, and a passive gear 340. The active gear 330 and the passive gear 340 are installed on left shaft ends of the lower roll 220 and the upper roll 210, respectively, and are engaged with each other. The large gear 320 is installed on a right shaft end of the lower roll 220.
A protruding handle shaft bearing seat 121a is disposed on the right front support 120a. A handle shaft 350 is supported on the handle shaft bearing seat 121a through a needle roller bearing 360. A bearing cover (not shown) is installed on the handle shaft bearing seat 121a through a fastening screw. The small gear 310 is disposed at an inner end of the handle shaft 350 through a key. A crank handle (not shown) is installed at an inner end of the handle shaft 350. The crank handle rotates to drive the handle shaft 350 to rotate. Also, the crank handle drives the small gear 310 to rotate. Through the engagement between the small gear 310 and the large gear 320, the small gear 310 drives the large gear 320 to rotate at a lower speed. The rotation of the large gear 320 also drives the lower roll 220 to rotate. The lower roll 220 rotates to further drive the active gear 330 to rotate. The upper roll 210 is driven to rotate through a transmission set formed of the active gear 330 and the passive gear 340 being engaged with each other. Rolling is accomplished with the rotation of the upper roll 210 and the lower roll 220.
To accommodate thickness differences among die sheets and knurling dies from different manufacturers, this embodiment uses a rolling gap adjustment mechanism to adjust the rolling gap between the upper roll 210 and the lower roll 220.
The rolling gap adjustment mechanism in the embodiment includes a dual-joint slope block 400 installed on a bottom portion of the guide rail plate 140. The dual-joint slope block 400 and the guide rail plate 140 form a first movement set, and slope block protruding openings 111, 111a are provided at upper portions of the left frame 100 and the right frame 100a. When the dual-joint slope block 400 moves horizontally along the guide rail plate 140, two ends of the dual-joint slope block 400 can extend from the slope block protruding openings 111, 111a.
Active slopes 410, 410a fitting passive slopes 231, 231a of the sliding blocks 230, 230a are arranged on bottom surfaces of the two ends of the dual-joint slope block 400. The active slopes 410, 410a and the passive slopes 231, 231a form second movement sets. Further, a movement handle 420 is disposed on the dual-joint slope block 400. By means of the movement handle 420, the dual-joint slope block 400 can move horizontally. Through the second movement sets formed of the active slopes 410, 410a and the passive slopes 231, 231a, the horizontal movement of the dual-joint slope block 400 is converted into vertical movement of the sliding blocks 230, 230a. The vertical movement of the sliding blocks 230, 230a drives the upper roll 210 to move vertically relative to the lower roll 220, so as to adjust the rolling gap between the upper roll 210 and the lower roll 220.
To perform shift adjustment for the rolling gap between the upper roll 210 and the lower roll 220, in this embodiment, a guide rail groove 141 arranged along the length direction of the guide rail plate 140 is provided on the guide rail plate 140. A sliding key 420 and a pair of trench plates 430, 430a are arranged inside the guide rail groove 141. The sliding key 420 is connected to the dual-joint slope block 400. The pair of trench plates 430, 430a is arranged at two sides of the sliding key 420.
A radial positioning hole 421 is provided on the sliding key 420. A pair of positioning steel balls 440, 440a and a positioning spring 450 are arranged inside the radial positioning hole 421. The positioning spring 450 is arranged between the pair of steel balls 440, 440a. Several positioning trenches 431 are provided at an interval on the trench plate 450 (certainly several positioning holes may also be provided), so as to form a plurality of shifts. The adjustment amount of the rolling gap between the upper roll 210 and the lower roll 220 each time depends on the space between two adjacent positioning trenches 431.
When the sliding key 420 moves, the positioning steel ball 440 is pressed into one random positioning trench 431 under the effect of the positioning spring 450, so as to position the dual-joint slope block 400, thereby ensuring the stability of the dual-joint slope block 400 at a new position and ensuring desirable handgrip of the dual-joint slope block 400 in the movement process.
The working principle of the foregoing rolling gap adjustment mechanism is as follows: Refer to
Refer to
Refer to
Sliding block reset springs are disposed between top surfaces of the sliding blocks 230, 230a and the horizontal stop. The bottom surfaces of the sliding blocks 230, 230a are passive slopes 231, 231a with the same inclined angle and parallel to each other. Active slopes 410, 410a fitting the passive slopes 231, 231a of the sliding blocks 230, 230a are arranged on the top surfaces of the two ends of the dual-joint slope block 400. The working principle is basically the same as that in Embodiment 1.
This embodiment is basically the same as Embodiment 1. Refer to
Refer to
Refer to
This embodiment and Embodiment 1 are basically the same in structure. This embodiment is different from Embodiment 1 in that: Refer to
This embodiment is basically the same as Embodiment 1 in structure. This embodiment is different from Embodiment 1 in that: Refer to
In addition, a screw hole 142 is provided at the left end of the dual-joint slope block 140. A bolt support portion 112 is disposed on the left frame 100. A radially rotatable but axially-constrained screw rod 113 is arranged on the bolt support portion 112. The screw rod 113 is screwed inside the screw hole 142. The screw rod 113 rotates to drive the dual-joint slope block 140 to move horizontally, so as to drive the sliding blocks 230, 230a to move vertically, thereby adjusting the rolling gap between the upper roll 210 and the lower roll 220.
This embodiment is different from Embodiment 1 in the rolling gap adjustment mechanism. Refer to
The top portions of the left frame 100 and the right frame 100a are connected through an upper connecting plate 140a. The decorative material rolling mill having an adjustable roll gap depends on a pair of rolls to work. The pair of rolls includes an upper roll 210 and a lower roll 220. The lower roll 220 is supported on the lower portions of the left frame 100 and the right frame 100a through a pair of ball bearings 221, 221a.
A left horizontal stop 150 is disposed at the middle portion of the left support 100. A right horizontal stop 150a is disposed at the middle portion of the right support 100a. A sliding cavity 160 for the sliding block to slide vertically is formed in the space located above the horizontal stop 150 of the left support 100. A sliding cavity 160a for the sliding block to slide vertically is formed in the space located above the horizontal stop 150a of the right support 100a.
Sliding blocks 230, 230a are placed inside the sliding cavities 160, 160a, respectively. Sliding block reset springs 240, 240a are disposed between the bottom surfaces of the sliding blocks 230, 230a and the horizontal stops 150, 150a. The top surfaces of the sliding blocks 230, 230a are planes.
The two ends of the upper roll 210 are supported on the sliding blocks 230, 230a through needle roller bearings 211, 211a, respectively.
A pair of cams 610, 610a is arranged inside the sliding cavities 160, 160a and contacts the top surfaces of the sliding blocks 230, 230a. A cam shaft 620 is axially supported on the left frame 100 and extends from the left frame 100. Two ends of the cam shaft 620 and the pair of cams 610, 610a are connected through a key. A crank handle (not shown) is arranged on the shaft end of the cam shaft extending from the left frame 100.
The crank handle rotates to drive the cam shaft 620 to rotate. The pair of cams 610, 610a acts on the sliding blocks 230, 230a, respectively, to drive the sliding blocks 230, 230a to move downward. The upward movement of the sliding blocks 230, 230a is implemented depending on the sliding block reset springs 240, 240a. The rest structures of this embodiment are the same as those in Embodiment 1. The working principle of rolling is also the same as that in Embodiment 1.
This embodiment is different from Embodiment 1 in the rolling gap adjustment mechanism. Refer to
The top portions of the left frame 100 and the right frame 100a are connected through an upper connecting plate 140a. The decorative material rolling mill having an adjustable roll gap depends on a pair of rolls to work. The pair of rolls includes an upper roll 210 and a lower roll 220. The lower roll 220 is supported on the lower portions of the left frame 100 and right frame 100a through a pair of ball bearings 221, 221a.
A left horizontal stop 150 is disposed at the middle portion of the left support 100. A right horizontal stop 150a is disposed at the middle portion of the right support 100a. A sliding cavity 160 for the sliding block to slide vertically is formed in the space located above the horizontal stop 150 of the left support 100. A sliding cavity 160a for the sliding block to slide vertically is formed in the space located above the horizontal stop 150a of the right support 100a.
Sliding blocks 230, 230a are placed inside the sliding cavities 160, 160a, respectively. The two ends of the upper roll 210 are supported on the sliding blocks 230, 230a through needle roller bearings 211, 211a, respectively.
A pair of screw rods 630, 630a is arranged inside the sliding cavities 160, 160a and is in threaded connection to the screw holes 232, 232a inside the sliding blocks 230, 230a. The dual-joint worm 640 is axially supported on the left frame 100 and extends from the left frame 100. Worm segments 641, 641a are disposed at the two ends of the dual-joint worm 640. The worm segments 641, 641a are engaged with the worm gears 631, 631a, respectively. A crank handle (not shown) is arranged on the shaft end of the dual-joint worm 640 extending from the left frame 100.
The crank handle rotates to drive the dual-joint worm 640 to rotate. The rotation of the dual-joint worm 640 drives the worm segments 641, 641a to rotate. Through the engagement between the worm segments 641, 641a and the worm gears 631, 631a, the worm gears 631, 631a are driven to rotate. The worm gears 631, 631a then drive the screw rods 630, 630a to rotate. The screw rods 630, 630a drive the sliding blocks 230, 230a to move vertically to implement the adjustment of the rolling gap between the upper roll 210 and the lower roll 220. The working principle of rolling is also the same as that in Embodiment 1.
Refer to
Bottom portions of the left frame 100 and the right frame 100a are connected through a lower connecting plate 130. In connecting, the lower connecting plate 130 further connects the left front support 110 and the left rear support 120 and connects the right front support 110a and the right rear support 120a through a fastening bolt.
Top portions of the left frame 100 and the right frame 100a are connected through an upper connecting plate 140b. In connecting, the upper connecting plate 140b further connects the left front support 110 and the left rear support 120 and connects the right front support 110a and the right rear support 120a through a fastening bolt.
When being connected adopting the foregoing manner, the left frame 100, the right frame 100a, the lower connecting plate 130, and the upper connecting plate 140b form a rectangular frame.
The decorative material rolling mill having an adjustable roll gap depends on a pair of rolls to work. The pair of rolls includes an upper roll 210 and a lower roll 220. The lower roll 220 is supported on lower portions of the left frame 100 and the right frame 100a through a pair of ball bearings 221, 221a, that is, supported on the lower portions of the left front support 110 and the left rear support 120 and the lower portions of the right front support 110a and the right rear support 120a.
A left horizontal stop 150 is connected between middle portions of the left front support 110 and the left rear support 120. A right horizontal stop 150a is connected between the middle portions of the right front support 110a and the right rear support 120a. A sliding cavity 160 for the sliding block to slide vertically is formed in the space located above the horizontal stop 150 of the left front support 110 and the left rear support 120. A sliding cavity 160a for the sliding block to slide vertically is formed in the space located above the horizontal stop 150a of the right front support 110a and the right rear support 120a.
Sliding blocks 230, 230a are placed inside the sliding cavities 160, 160a, respectively, and top surfaces of the sliding blocks 230, 230a are planes.
Two ends of the upper roll 210 are supported on the sliding blocks 230, 230a through needle roller bearings 211, 211a, respectively.
The rotation of the upper roll 210 and the lower roll 220 depends on a driving mechanism. The driving mechanism includes a small gear 310, a large gear 320, an active gear 330, and a passive gear 340. The active gear 330 and the passive gear 340 are installed on left shaft ends of the lower roll 220 and the upper roll 210, respectively, and are engaged with each other. The large gear 320 is installed on a right shaft end of the lower roll 220.
A protruding handle shaft bearing seat 121a is disposed on the right front support 120a. The handle shaft 350 is supported on the handle shaft bearing seat 121a through a needle roller bearing 360. A bearing cover (not shown) is installed on the handle shaft bearing seat 121a through a fastening screw. The small gear 310 is disposed at an inner end of the handle shaft 350 through a key. A crank handle (not shown) is installed at an outer end of the handle shaft 350. The crank handle rotates to drive the handle shaft 350 to rotate. The crank handle also drives the small gear 310 to rotate. Through the engagement between the small gear 310 and the large gear 320, the small gear 310 drives the large gear 320 to rotate at a lower speed. The rotation of the large gear 320 also drives the lower roll 220 to rotate. The rotation of the lower roll 220 also drives the active gear 330 to rotate. The upper roll 210 is driven to rotate through a transmission set formed of the active gear 330 and the passive gear 340 being engaged with each other. Rolling is accomplished with the rotation of the upper roll 210 and the lower roll 220.
To accommodate thickness differences among die sheets and knurling dies from different manufacturers, this embodiment uses a rolling gap adjustment mechanism to adjust the rolling gap between the upper roll 210 and the lower roll 220.
The rolling gap adjustment mechanism in this embodiment includes frame slopes 113, 113a arranged inside top portions of the left frame 100 and the right frame 100a and a positioning guide rail 710 fixed at the middle position of the upper connecting plate 140b. The inclined angle of the positioning guide rail 710 is consistent with the angle of the frame slope. Guide rail cover plates 711, 711a are fixedly installed at two ends of the positioning guide rail 710.
A dual-joint slope block 720 is installed below the upper connecting plate 140b. Two ends of the dual-joint slope block 720 extend between top surfaces of the sliding blocks 230, 230a at the two ends of the upper roll 210 and the frame slopes 113, 113a. Passive slopes 721, 721a fitting the frame slopes 113, 113a are arranged at the top portions of the two ends of the dual-joint slope block 720. The frame slopes 113, 113a and the passive slopes 721, 721a form movement sets. Sliding block acting portions 722, 722a are arranged at the bottom portions of the two ends of the dual-joint slope block 720. The sliding block acting portions 722, 722a act on the sliding blocks 230, 230a.
A positioning sliding block 730 inserted inside the positioning guide rail 710 is disposed at the middle position of the dual-joint slope block 720. One end of the positioning sliding block 730 comes out from the guide rail cover plate 711a. A positioning guide rail reset spring 740 is arranged between the other end of the positioning sliding block 730 and the guide rail cover plate 711.
A probe 770 is installed through a radial fixation screw 760 and an axial adjustment screw 750 on the part of the positioning sliding block 730 coming from the guide rail cover plate 711a. The probe 770 is located above the rolling workbench 800. The specific installation manner is as follows: A radial screw hole 731 is provided on the part of the positioning sliding block 730 coming from the guide rail cover plate 711a. The radial fixation screw 760 passes through a waist-shaped hole 771 on the probe 770 to be screwed inside the radial screw hole 731. The object of disposing waist-shaped hole 771 is mainly to facilitate the adjustment of the height of the probe 770, and also compensate for the abrasion of the probe 770. An axial through hole 141b is provided on the upper connecting plate 140b. An axial screw hole 732 is provided on the part of the positioning sliding block 730 coming from the guide rail cover plate 711a. The axial adjustment screw 750 passes through the axial through hole 141b and is screwed through the axial screw hole 732 to press the top surface of the probe 770. The height of the probe 770 can be adjusted through the axial adjustment screw 750.
Refer to
The crank handle rotates to drive the handle shaft 350 to rotate. The crank handle also drives the small gear 310 to rotate. Through the engagement between the small gear 310 and the large gear 320, the small gear 310 drives the large gear 320 to rotate at a lower speed. The rotation of the large gear 320 also drives the lower roll 220 to rotate. The rotation of the lower roll 220 also drives the active gear 330 to rotate. The upper roll 210 is driven to rotate through a transmission set formed of the active gear 330 and the passive gear 340 being engaged with each other. The rotation of the upper roll 210 and the lower roll 220 drives the shearing die 500 to move forward to perform rolling on the part that requires rolling. When the rolling is finished, the shearing die 500 is pushed out. The positioning sliding block 730 and the probe 770 are reset through the positioning guide rail reset spring 740, so as to enter a next rolling state.
Compared with the prior art, the embodiment adopts two standardized rolling plates to greatly reduce the running cost. Through the measurement of a probe, an accurate roll gap is obtained between an upper roll and a lower roll, thereby significantly increasing the rolling precision, achieving a very stable rolling effect, and effectively ensuring the quality of roll die sheets, upper rolling plates and lower rolling plates.
Generally, after core-drawing of a hole of a cast, an axial core-drawing tilt often exists. For a bearing hole having a high assembly precision, after casting forming, shearing process is further required. In the foregoing embodiment of the present invention, the left frame 100 includes the left front support 110 and the left rear support 120 along the center of the bearing hole. The right frame 100a includes the right front support 110a and the right rear support 120a along the center of the bearing hole, and the formation is achieved by adopting a forming method of casting along a bearing aperture, which eliminates the axial taper of a bearing hole, and also solves the axial positioning of the bearing and the sliding block along the roll on the frame, thereby omitting a stop ring required by axial positioning of a bearing and a guide pressing plate required by axial positioning of a sliding block. Further, the through holes for screws required for the assembly of the frame can be cast one by one. A core-drawing structure is omitted in a casting mold, thereby reduce the fabrication cost for casting molds, which reduces shearing process for metal, reduces the number of parts to form, and reduces the production cost.
Number | Date | Country | Kind |
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201110287244.9 | Sep 2011 | CN | national |
201120360880.5 | Sep 2012 | CN | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CN2012/001292 | 9/21/2012 | WO | 00 | 3/21/2014 |