阅读说明：本技术 一种橡胶染色方法 (Rubber dyeing method ) 是由 张志勇 于 2021-09-18 设计创作，主要内容包括：本发明属于橡胶生产领域,尤其是涉及一种橡胶染色方法。该方法是配合一种橡胶染色装置进行的,该一种橡胶染色装置包括主机架,主机架设有大转盘电动机,大转盘电动机的伸出轴固设有大转盘转轴,大转盘转轴设有大转盘,大转盘两端设有大转盘槽,每个大转盘槽内设有摆位机构,主机架设有主机架槽,主机架固设有齿轮箱,主机架的有挤压电动机,挤压电动机的输出轴固设有主动齿轮转轴,主动齿轮转轴上固设有主动齿轮,齿轮箱内设有可转动的从动齿轮转轴,从动齿轮转轴上固设有从动齿轮,从动齿轮转轴和主动齿轮转轴的末端固设有挤压滚筒转轴,挤压滚筒转轴和齿轮箱上设有搓擦机构,挤压滚筒转轴上周向固设有挤压滚筒,挤压滚筒内设有轴向位移机构。(The invention belongs to the field of rubber production, and particularly relates to a rubber dyeing method. The method is carried out by matching with a rubber dyeing device which comprises a main frame, wherein the main frame is provided with a large turntable motor, an extension shaft of the large turntable motor is fixedly provided with a large turntable rotating shaft, the large turntable rotating shaft is provided with a large turntable, large turntable grooves are arranged at two ends of the large turntable, a positioning mechanism is arranged in each large turntable groove, the main frame is provided with a main frame groove, the main frame is fixedly provided with a gear box, an extrusion motor is arranged on the main frame, an output shaft of the extrusion motor is fixedly provided with a driving gear rotating shaft, a driving gear is fixedly arranged on the driving gear rotating shaft, a rotatable driven gear rotating shaft is arranged in the gear box, a driven gear is fixedly arranged on the driven gear rotating shaft, the tail ends of the driven gear rotating shaft and the driving gear rotating shaft are fixedly provided with an extrusion roller rotating shaft, the extrusion roller rotating shaft and the gear box are provided with a rubbing mechanism, and an extrusion roller is circumferentially fixedly arranged on the extrusion roller rotating shaft, an axial displacement mechanism is arranged in the extrusion roller.)

1. A rubber dyeing method is matched with a rubber dyeing device, the rubber dyeing device comprises a main frame (25), a large turntable motor (23) is fixedly arranged on the large end face side of the main frame (25), a large turntable rotating shaft (22) is fixedly arranged on an extending shaft of the large turntable motor (23), a large turntable (16) is fixedly arranged at the tail end of the large turntable rotating shaft (22), large turntable grooves (21) are symmetrically formed in two ends of the large turntable (16), a positioning mechanism is arranged in each large turntable groove (21), a coiling roller (41) is arranged at the tail end of each positioning mechanism, a clamping mechanism is arranged on each coiling roller (41), a main frame groove (24) is formed in the large end face side of the main frame (25), a gear box (29) is fixedly arranged on the small end face side of the main frame (25), an extrusion motor (30) is fixedly arranged on the small end face side of the main frame (25), the output shaft of extrusion motor (30) has set firmly driving gear pivot (27), driving gear (28) have set firmly on driving gear pivot (27), be equipped with rotatable driven gear pivot (46) in gear box (29), driven gear pivot (46) have set firmly driven gear (45), driven gear pivot (46) with the end of driving gear pivot (27) has set firmly squeeze roll pivot (36), squeeze roll pivot (36) with be equipped with on gear box (29) and rub the mechanism with the hands, circumference has set firmly squeeze roll (34) on squeeze roll pivot (36), be equipped with axial displacement mechanism in squeeze roll (34).

2. A method for dyeing rubber according to claim 1, characterized in that: the swing mechanism comprises a rotary swing rotating shaft (20) arranged in a large rotary disc groove (21), a swing gear (19) is fixedly arranged on the swing rotating shaft (20), a sliding rod sliding groove (48) is formed in the side surface of the large rotary disc groove (21) of the large rotary disc (16), a sliding rod (17) capable of sliding in a reciprocating manner is arranged in the sliding rod sliding groove (48), a rack (18) is fixedly arranged on the sliding rod (17), the rack (18) is meshed with the swing gear (19), a traction rope (13) is fixedly wound on the swing rotating shaft (20), a traction roller frame (15) is fixedly arranged on the side surface of the tail end of the sliding rod (17), a traction roller (14) is arranged on the traction roller frame (15), a swing rotating shaft (10) is fixedly arranged at the tail end of the sliding rod (17), a coil motor frame (12) is fixedly arranged on the swing rotating shaft (10), the other end of the traction rope (13) is fixedly arranged on the coiling motor frame (12).

3. A method for dyeing rubber according to claim 2, characterized in that: the coil motor is characterized in that a coil motor (11) is fixedly arranged on the coil motor frame (12), a connecting rotating shaft (54) is fixedly arranged on an output shaft of the coil motor (11), a connecting bearing (53) is arranged in the connecting rotating shaft (54), a coil rotating shaft (38) is fixedly arranged in a hole of the connecting bearing (53), and a connecting rotating shaft convex block (56) is fixedly arranged on the connecting rotating shaft (54).

4. A method for dyeing rubber according to claim 1, characterized in that: the clamping mechanism comprises every be equipped with extrusion splint sleeve (39) that can free rotation on coil stock pivot (38), extrusion splint (44) have set firmly on extrusion splint sleeve (39), coil stock cylinder (41) have set firmly on extrusion splint sleeve (39), set up in coil stock cylinder (41) and trigger splint spout (66), be equipped with reciprocating sliding's trigger splint slider (40) in trigger splint spout (66), trigger splint slider (40) with be equipped with between trigger splint spout (66) and trigger splint spring (67), trigger splint slider (40) have set firmly on trigger splint slider (33), splint spout (43) have been seted up on coil stock cylinder (41), trigger splint (33) with extrusion splint (44) are in slide in splint spout (43), coil stock cylinder (41) lower part has set firmly coil stock cylinder thing (42), trigger splint (33) with splint spring (32) have set firmly between extrusion splint (44), trigger splint (33) with between extrusion splint (44) the splint spring (32) outside has set firmly soft area (31).

5. A method for dyeing rubber according to claim 4, characterized in that: the side end of the extrusion splint sleeve (39) is fixedly provided with a connecting disk body (57) capable of rotating around the coiling rotating shaft (38), a connecting sliding groove (59) is formed in the connecting disk body (57), a connecting sliding block (52) capable of sliding in a reciprocating mode is arranged in the connecting sliding groove (59), a connecting spring (60) is fixedly arranged between the connecting sliding block (52) and the connecting sliding groove (59), a connecting sliding block limiting block (51) is fixedly arranged on the connecting sliding block (52), a connecting sliding block limiting block clamping groove (58) is formed in the connecting disk body (57), the connecting sliding block limiting block (51) can axially slide in the connecting sliding block limiting block clamping groove (58), a connecting sliding block clamping groove (55) is formed in the connecting sliding block (52), and the connecting sliding block clamping groove (55) can be circumferentially clamped with the connecting rotating shaft lug (56).

6. A method for dyeing rubber according to claim 4, characterized in that: the coil stock roller (41) is provided with a trigger sliding groove (62), a trigger sliding block (65) capable of sliding in a reciprocating mode is arranged in the trigger sliding groove (62), a trigger spring (63) is fixedly arranged between the trigger sliding block (65) and the trigger sliding groove (62), two sides of the trigger sliding groove (62) are provided with conductive loops (61), and the bottom of the trigger sliding block (65) is provided with a conductive layer (64).

7. A method for dyeing rubber according to claim 1, characterized in that: the rubbing mechanism comprises a rotating shaft (36) of each squeezing roller, wherein a sliding groove (49) of the pressurizing roller is fixedly arranged on the rotating shaft (50), each squeezing roller (34) is internally provided with a sliding groove (49) of the pressurizing roller, and the rubbing mechanism (50) can axially slide in the corresponding sliding groove (49) of the pressurizing roller.

8. A method for dyeing rubber according to claim 1, characterized in that: including axial displacement mechanism include every squeeze roll pivot (36) end has set firmly squeeze roll bottom plate (37), squeeze roll bottom plate (37) with be equipped with squeeze roll spring (35) between squeeze roll (34), squeeze roll (34) are equipped with two squeeze roll pressurized round head pieces (47) at the side symmetry of input, set firmly two sets of four button heads on gear box (29) and press piece (26), every group the button head press piece (26) butt in squeeze roll (34) are in the side of input.

Technical Field

The invention belongs to the field of rubber production, and particularly relates to a rubber dyeing method.

Background

With the continuous development of rubber products, the color of rubber is more and more required. Among the prior art, rely on the manpower to dye the material from top to bottom, the trouble just has accident risk to can only carry out the extrusion dyeing of a dimension, efficiency is lower. Therefore, an efficient rubber dyeing method which does not depend on manpower is designed.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a rubber dyeing method.

In order to achieve the purpose, the invention adopts the following technical scheme: a rubber dyeing method is matched with a rubber dyeing device, the rubber dyeing device comprises a main frame, a large turntable motor is fixedly arranged on the large end face side of the main frame, a large turntable rotating shaft is fixedly arranged on an extension shaft of the large turntable motor, a large turntable is fixedly arranged at the tail end of the large turntable rotating shaft, large turntable grooves are symmetrically formed in two ends of the large turntable, a positioning mechanism is arranged in each large turntable groove, a coiling roller is arranged at the tail end of each positioning mechanism, a clamping mechanism is arranged on each coiling roller, a main frame groove is formed in the large end face side of the main frame, a gear box is fixedly arranged on the small end face side of the main frame, an extrusion motor is fixedly arranged on the small end face side of the main frame, a driving gear rotating shaft is fixedly arranged on an output shaft of the extrusion motor, and a driving gear is fixedly arranged on the driving gear rotating shaft, the automatic rubbing machine is characterized in that a rotatable driven gear rotating shaft is arranged in the gear box, a driven gear is fixedly arranged on the driven gear rotating shaft, a squeezing roller rotating shaft is fixedly arranged at the tail ends of the driven gear rotating shaft and the driving gear rotating shaft, a rubbing mechanism is arranged on the squeezing roller rotating shaft and the gear box, a squeezing roller is fixedly arranged on the squeezing roller rotating shaft in the circumferential direction, and an axial displacement mechanism is arranged in the squeezing roller.

Preferably, a rotatable swing rotating shaft is arranged in the large rotating disc groove, a swing gear is fixedly arranged on the swing rotating shaft, a sliding rod sliding groove is formed in the side face of the large rotating disc groove, a sliding rod capable of sliding in a reciprocating mode is arranged in the sliding rod sliding groove, a rack is fixedly arranged on the sliding rod and meshed with the swing gear, a traction rope is fixedly wound on the swing rotating shaft, a traction roller frame is fixedly arranged on the side face of the tail end of the sliding rod, a traction roller is arranged on the traction roller frame, a swing rotating shaft is fixedly arranged at the tail end of the sliding rod, a coiling motor frame is fixedly arranged on the swing rotating shaft, and the other end of the traction rope is fixedly arranged on the coiling motor frame.

Preferably, a coil motor is fixedly arranged on the coil motor rack, a connecting rotating shaft is fixedly arranged on an output shaft of the coil motor, a connecting bearing is arranged in the connecting rotating shaft, a coil rotating shaft is fixedly arranged in a connecting bearing hole, and a connecting rotating shaft bump is fixedly arranged on the connecting rotating shaft.

Preferably, each coil rotating shaft is provided with a freely rotatable extrusion clamping plate sleeve, an extrusion clamping plate is fixedly arranged on the extrusion clamping plate sleeve, a coiling roller is fixedly arranged on the extrusion clamping plate sleeve, a triggering clamping plate sliding groove is arranged in the coiling roller, a trigger clamping plate sliding block capable of sliding back and forth is arranged in the trigger clamping plate sliding groove, a trigger clamping plate spring is arranged between the trigger clamping plate sliding block and the trigger clamping plate sliding groove, the trigger clamping plate sliding block is fixedly provided with a trigger clamping plate, the coiling drum is provided with a clamping plate sliding groove, the triggering clamp plate and the extruding clamp plate slide in the clamp plate chute, the lower part of the coiling roller is fixedly provided with a coiling roller counterweight, the soft belt type rubber belt conveyor is characterized in that a clamping plate spring is fixedly arranged between the trigger clamping plate and the extrusion clamping plate, and a soft belt is fixedly arranged between the trigger clamping plate and the extrusion clamping plate and outside the clamping plate spring.

Preferably, the telescopic side of extrusion splint has set firmly can be around coil stock pivot pivoted connection disk body, the internal connection spout that has seted up of connection pad, be equipped with reciprocating sliding's link block in the connection spout, link block with link spring has set firmly between the spout, the link block has set firmly the link block stopper, the internal link block stopper draw-in groove of having seted up of connection pad, the link block stopper can axial slip in the link block stopper draw-in groove, the link block draw-in groove has been seted up on the link block, the link block draw-in groove can with it dies to connect pivot lug circumference card.

Preferably, a trigger chute is formed in the winding drum, a trigger slider capable of sliding back and forth is arranged in the trigger chute, a trigger spring is fixedly arranged between the trigger slider and the trigger chute, conductive loops are arranged on two sides of the trigger chute, and a conductive layer is arranged at the bottom of the trigger slider.

Preferably, each of the rotating shafts of the pressing rollers is fixedly provided with a pressing roller chute, and each of the pressing rollers is internally provided with a pressing roller chute which can axially slide in the corresponding pressing roller chute.

Preferably, every the terminal squeeze roll bottom plate that has set firmly of squeeze roll pivot, squeeze roll bottom plate with be equipped with the squeeze roll spring between the squeeze roll, squeeze roll is equipped with two squeeze roll pressurized round head blocks in the side symmetry of input, set firmly two sets of four button head on the gear box and press the piece, every group the button head press the piece butt in the side of squeeze roll at the input.

Has the advantages that:

the invention provides a rubber dyeing method through improvement, and compared with the prior art, the rubber dyeing method has the following improvements and advantages:

1. through the cooperation of the round-head pressing block 26, the squeezing roller 34, the squeezing roller pressed round-head block 47 and the auxiliary mechanisms thereof, the squeezing of two dimensions of rubber is realized, and the dyeing efficiency is improved.

2. The cooperation of the trigger clamp 33 and the pressing clamp 44 and the auxiliary mechanism thereof realizes the automatic clamping and releasing of the rubber.

3. The mechanism frees labor force through the large turntable 16 and all mechanisms on the large turntable, and avoids possible labor accidents.

Drawings

FIG. 1 is a cross-sectional view of the mechanism of the present design;

FIG. 2 is a cross-sectional view taken at A-A of FIG. 1;

FIG. 3 is a cross-sectional view taken at B-B of FIG. 1;

FIG. 4 is a cross-sectional view taken at C-C of FIG. 1;

FIG. 5 is a cross-sectional view taken at D-D of FIG. 1;

FIG. 6 is an enlarged view of a portion E of FIG. 1;

FIG. 7 is a cross-sectional view taken at F-F of FIG. 4;

fig. 8 is a partial enlarged view at G in fig. 2.

In the figure, a swing rotary shaft 10, a coiling motor 11, a coiling motor frame 12, a traction rope 13, a traction roller 14, a traction roller frame 15, a large rotary table 16, a sliding rod 17, a rack 18, a swing gear 19, a swing rotary shaft 20, a large rotary table groove 21, a large rotary table rotary shaft 22, a large rotary table motor 23, a main frame groove 24, a main frame 25, a round head pressing block 26, a driving gear rotary shaft 27, a driving gear 28, a gear box 29, an extrusion motor 30, a soft belt 31, a clamping plate spring 32, a trigger clamping plate 33, an extrusion roller 34, an extrusion roller spring 35, an extrusion roller rotary shaft 36, an extrusion roller bottom plate 37, a coiling rotary shaft 38, an extrusion clamping plate sleeve 39, a trigger clamping plate slide block 40, a coiling roller 41, a coiling roller counterweight 42, a clamping plate sliding groove 43, an extrusion clamping plate 44, a driven gear 45, a driven gear rotary shaft 46, an extrusion roller pressed round head block 47, a sliding rod sliding groove 48, a traction roller slide rod sliding groove 48, a traction roller and a traction roller, The device comprises a pressurizing roller sliding groove 49, a squeezing roller rotating shaft limiting block 50, a connecting slider limiting block 51, a connecting slider 52, a connecting bearing 53, a connecting rotating shaft 54, a connecting slider clamping groove 55, a connecting rotating shaft bump 56, a connecting disc body 57, a connecting slider limiting block clamping groove 58, a connecting sliding groove 59, a connecting spring 60, a conductive loop 61, a triggering sliding groove 62, a triggering spring 63, a conductive layer 64, a triggering slider 65, a triggering clamp plate sliding groove 66 and a triggering clamp plate spring 67.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

As shown in fig. 1 and 2, a rubber dyeing method is performed in cooperation with a rubber dyeing apparatus, the rubber dyeing apparatus includes a main frame 25, a large turntable motor 23 is fixedly arranged on a large end surface side of the main frame 25, a large turntable rotating shaft 22 is fixedly arranged on an extending shaft of the large turntable motor 23, a large turntable 16 is fixedly arranged at a tail end of the large turntable rotating shaft 22, large turntable grooves 21 are symmetrically formed at two ends of the large turntable 16, a positioning mechanism is arranged in each large turntable groove 21, a material rolling roller 41 is arranged at a tail end of each positioning mechanism, a clamping mechanism is arranged on each material rolling roller 41, a main frame groove 24 is arranged on the large end surface side of the main frame 25, a gear box 29 is fixedly arranged on a small end surface side of the main frame 25, an extrusion motor 30 is fixedly arranged on a small end surface side of the main frame 25, a driving gear rotating shaft 27 is fixedly arranged on an output shaft of the extrusion motor 30, a driving gear 28 is fixedly arranged on the driving gear rotating shaft 27, a rotatable driven gear rotating shaft 46 is arranged in the gear box 29, a driven gear 45 is fixedly arranged on the driven gear rotating shaft 46, a squeezing roller rotating shaft 36 is fixedly arranged at the tail ends of the driven gear rotating shaft 46 and the driving gear rotating shaft 27, rubbing mechanisms are arranged on the squeezing roller rotating shaft 36 and the gear box 29, a squeezing roller 34 is fixedly arranged on the squeezing roller rotating shaft 36 in the circumferential direction, and an axial displacement mechanism is arranged in the squeezing roller 34.

As shown in fig. 1 and 5, a rotatable swing rotating shaft 20 is arranged in a large rotating disc groove 21, a swing gear 19 is fixedly arranged on the swing rotating shaft 20, a sliding rod sliding groove 48 is arranged on the side surface of the large rotating disc groove 21 of the large rotating disc 16, a sliding rod 17 capable of sliding in a reciprocating manner is arranged in the sliding rod sliding groove 48, a rack 18 is fixedly arranged on the sliding rod 17, the rack 18 is meshed with the swing gear 19, a traction rope 13 is fixedly wound on the swing rotating shaft 20, a traction roller frame 15 is fixedly arranged on the side surface of the tail end of the sliding rod 17, a traction roller 14 is arranged on the traction roller frame 15, a swing rotating shaft 10 is fixedly arranged at the tail end of the sliding rod 17, a coiling motor frame 12 is fixedly arranged on the swing rotating shaft 10, and the other end of the traction rope 13 is fixedly arranged on the coiling motor frame 12.

As shown in fig. 1, a coil motor 11 is fixedly arranged on the coil motor frame 12, a connecting shaft 54 is fixedly arranged on an output shaft of the coil motor 11, a connecting bearing 53 is arranged in the connecting shaft 54, a coil rotating shaft 38 is fixedly arranged in a hole of the connecting bearing 53, and a connecting shaft protrusion 56 is fixedly arranged on the connecting shaft 54.

As shown in fig. 2, each coil material rotating shaft 38 is provided with a freely rotatable extrusion clamping plate sleeve 39, an extrusion clamping plate 44 is fixedly arranged on the extrusion clamping plate sleeve 39, a coil material roller 41 is fixedly arranged on the extrusion clamping plate sleeve 39, a trigger clamping plate sliding groove 66 is formed in the coil material roller 41, a trigger clamping plate sliding block 40 capable of sliding back and forth is arranged in the trigger clamping plate sliding groove 66, a trigger clamping plate spring 67 is arranged between the trigger clamping plate sliding block 40 and the trigger clamping plate sliding groove 66, a trigger clamping plate 33 is fixedly arranged on the trigger clamping plate sliding block 40, a clamping plate sliding groove 43 is formed in the coil material roller 41, the trigger clamping plate 33 and the extrusion clamping plate 44 slide in the clamping plate sliding groove 43, a coil material roller counterweight 42 is fixedly arranged at the lower part of the coil material roller 41, a clamping plate spring 32 is fixedly arranged between the trigger clamping plate 33 and the extrusion clamping plate 44, and a soft belt 31 is fixedly arranged between the trigger clamping plate 33 and the extrusion clamping plate 44 outside the clamping plate spring 32.

As shown in fig. 6, a connecting disc body 57 capable of rotating around the coil material rotating shaft 38 is fixedly arranged at a side end of the extrusion clamping plate sleeve 39, a connecting chute 59 is formed in the connecting disc body 57, a connecting slider 52 capable of sliding in a reciprocating manner is arranged in the connecting chute 59, a connecting spring 60 is fixedly arranged between the connecting slider 52 and the connecting chute 59, a connecting slider limiting block 51 is fixedly arranged on the connecting slider 52, a connecting slider limiting block clamping groove 58 is formed in the connecting disc body 57, the connecting slider limiting block 51 can axially slide in the connecting slider limiting block clamping groove 58, a connecting slider clamping groove 55 is formed in the connecting slider 52, and the connecting slider clamping groove 55 can be circumferentially clamped with the connecting rotating shaft protruding block 56.

As shown in fig. 8, a trigger chute 62 is formed on the winding drum 41, a trigger slider 65 capable of sliding back and forth is disposed in the trigger chute 62, a trigger spring 63 is fixedly disposed between the trigger slider 65 and the trigger chute 62, conductive loops 61 are disposed on two sides of the trigger chute 62, and a conductive layer 64 is disposed at the bottom of the trigger slider 65.

As shown in fig. 7, each of the pressing roller shafts 36 is fixedly provided with a 50, and each of the pressing rollers 34 is provided with a pressing roller sliding groove 49, 50 axially sliding in the corresponding pressing roller sliding groove 49.

As shown in fig. 4 and 7, a squeeze roller base plate 37 is fixedly arranged at the tail end of each squeeze roller rotating shaft 36, a squeeze roller spring 35 is arranged between the squeeze roller base plate 37 and the squeeze roller 34, two squeeze roller pressed round head blocks 47 are symmetrically arranged on the side surface of the input end of the squeeze roller 34, two groups of four round head pressing blocks 26 are fixedly arranged on the gear box 29, and each group of round head pressing blocks 26 abuts against the side surface of the squeeze roller 34 at the input end.

Initial position: the squeeze roller spring 35 is not pressed, and the squeeze roller 34 is spread open. The material rolling mechanism at the lower part is in a straightening state, and the material rolling mechanism at the upper part is in a folding state. The trigger clamp 33 and the pressing clamp 44 are set in the open state by the clamp spring 32, the trigger clamp slide 40 is pushed out by the trigger clamp slide groove 66, the link spring 60 is compressed by the link slide 52, and the trigger slide 65 is ejected by the trigger spring 63.

The rubber dyeing method comprises the following specific steps:

the first step is as follows: the friction rubber is extruded. The primary color rubber matched with the color blocks is placed between the extrusion rollers 34, the extrusion motor 30 is started, the extrusion rollers 34 start to rotate under the transmission of the driving gear rotating shaft 27, the driving gear 28, the driven gear 45 and the driven gear rotating shaft 46, and the rubber is extruded. During the rotation of the pressure roller 34, the pressure roller pressure button 47 is pressed by the button 26, and the pressure roller 34 is moved axially along the pressure roller axis 36 by the pressure roller chutes 49 and 50, in which movement the resistance of the pressure roller spring 35 is overcome. After the round head pressing block 26 releases the pressing of the pressing roller pressed round head block 47, the pressing roller 34 pops up and resets under the action of the pressing roller spring 35, the two-dimensional extrusion of rubber raw materials is realized in the process, and the accelerated mixing of color blocks is facilitated.

The second step is that: and (5) power connection of the coil stock. The coil motor 11 is started, the connecting rotating shaft 54 starts to rotate, the coil rotating shaft 38 does not rotate due to the existence of the connecting bearing 53, the connecting slide block 52 is electrically controlled to be popped out, the connecting slide block clamping groove 55 is clamped into the connecting rotating shaft lug 56, and the rotary motion is transmitted to the connecting disc body 57 and the extruding clamping plate sleeve 39. Under the action of inertia, the components such as the coil roller 41, the trigger clamp 33, the coil roller counterweight 42 and the like keep the original static state, and as the rubber falls into the clamp chute 43, the trigger clamp 33 and the extrusion clamp 44 clamp the rubber due to the rotation of the extrusion clamp sleeve 39, and start to pull the rubber to be wound on the coil roller 41.

The third step: and (5) discharging the materials again. After all the materials are wound on the material rolling roller 41, the large turntable motor 23 is started, the material rolling mechanism which is originally positioned at the lower part is conveyed to the upper part, and the material rolling mechanism which is originally positioned at the upper part is conveyed to the lower part. Because the swinging rotating shaft 10 is free to rotate, under the influence of gravity, the traction rope 13 is driven to move, the traction rope 13 drives the swinging gear 19 and the swinging rotating shaft 20 to rotate, the rotation of the swinging rotating shaft 20 drives the rack 18 and the sliding rod 17 to move, and the stretching and folding of the material rolling mechanism are completed. When the material reaches the top, the coil motor 11 stops rotating, the trigger clamp 33 and the pressing clamp 44 release the material, and the material falls back to between the pressing rollers 34 under the action of gravity to be pressed again.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.