阅读说明：本技术 一种蜂蜜栓剂及其加工系统 (Honey suppository and processing system thereof ) 是由 张小龙 于 2021-08-24 设计创作，主要内容包括：本发明提供了一种蜂蜜栓剂,同时提供了该蜂蜜栓剂的加工系统,加工系统包括均为自转设置的第一转动辊、第二转动辊以及第三转动辊,第二转动辊在靠近或远离第一转动辊和第三转动辊的路径上往复移动,第一转动辊、第二转动辊以及第三转动辊之间设置两端具有弧度且宽度可变的若干成型工位,条状物在第一转动辊、第二转动辊以及第三转动辊之间被切断并形成分别容入每一成型工位内的两端为弧形的若干栓状物。本发明解决了现有技术中热熔法使得蜂蜜栓剂表面产生凹凸对使用者造成二次伤害以及不能生产两端均具有弧度的蜂蜜栓剂的问题,同时也解决了搓捏法不适合大批量进行加工且蜂蜜栓剂品质得不到保证的问题。(The invention provides a honey suppository and also provides a processing system of the honey suppository, wherein the processing system comprises a first rotating roller, a second rotating roller and a third rotating roller which are all arranged in a self-rotating mode, the second rotating roller reciprocates on a path close to or far away from the first rotating roller and the third rotating roller, a plurality of forming stations with radian at two ends and variable width are arranged among the first rotating roller, the second rotating roller and the third rotating roller, and strips are cut among the first rotating roller, the second rotating roller and the third rotating roller and form a plurality of suppository-shaped objects with arc-shaped two ends which are respectively contained in each forming station. The invention solves the problems that the honey suppository surface generates concave-convex parts to cause secondary damage to users and the honey suppository with radian at two ends can not be produced by a hot melting method in the prior art, and also solves the problems that a kneading method is not suitable for large-scale processing and the quality of the honey suppository can not be ensured.)

1. The utility model provides a honey suppository system of processing, its characterized in that, is including first live-rollers, second live-rollers and the third live-rollers that are the rotation setting, wherein fixed mounting about first live-rollers and third live-rollers are and both axle center lines are the acute angle with horizontal angle, the second live-rollers is being close to or keeping away from first live-rollers with reciprocating motion on the route of third live-rollers, first live-rollers the second live-rollers and set up both ends between the third live-rollers and have a plurality of shaping stations that radian and width are changeable, the strip is in first live-rollers the second live-rollers and be cut off and form respectively between the third live-rollers and hold each both ends in the shaping station are a plurality of curved bolt form.

2. A honey suppository processing system as claimed in claim 1, characterized in that said first rotating roller, said second rotating roller and said third rotating roller are all hollow and a first electric heating rod is arranged in the hollow cavity.

3. A honey suppository processing system as claimed in claim 1 or 2, further comprising a mechanical kneading component for mechanically kneading the decocted material into a column, wherein the mechanical kneading component comprises four rollers with one end larger than the other end, the larger end of the four rollers is higher than the other end, the larger end of the four rollers is separated from the other end, the smaller end of the four rollers is gathered, and the material is extruded out from the end faces of the four rollers at the smaller end in the state of the column after being mechanically kneaded by the four rollers.

4. A honey suppository processing system as claimed in claim 3, characterized in that said mechanical kneading assembly further comprises a cabinet, four rollers are installed in said cabinet, a second electric heating rod is installed in said cabinet under all said rollers, a cabinet door is installed on the upper end of said cabinet, and a third electric heating rod is installed in said cabinet door.

5. The honey suppository processing system of claim 3, further comprising a reducing assembly for receiving the mechanically kneaded column, said reducing assembly comprising a horizontally disposed base plate and a plurality of pairs of reducing wheels rotatably mounted horizontally on said base plate; wherein a plurality of electric heating rings corresponding to the reducing wheels are arranged below the bottom plate.

6. A honey suppository processing system as claimed in claim 5, further comprising a cutter for cutting off said column; a buffer plate is arranged between the cutter and one end of the bottom plate far away from the roller, and a first electric heating plate is arranged below the buffer plate; the buffer board is close to the one end of cutter still installs at least a pair of leading wheel, still install on the buffer board with the guide block that the cutter is close to, be provided with on the guide block with two the perforation just right of leading wheel.

7. A honey suppository processing system as claimed in claim 6, wherein said base plate is further provided with a plurality of scrapers against the surfaces of each diameter reducing wheel and each guide wheel, said scrapers being arranged side by side in pairs on the side of each diameter reducing wheel or each guide wheel remote from said roller and spaced from each other.

8. A honey suppository processing system as claimed in claim 6, further comprising a spill plate pressed over and in sliding contact with both diameter reducing wheels or both guide wheels.

9. A honey suppository processing system according to claim 1 or 2, further comprising a conveyor belt for receiving the noodles, said conveyor belt being mounted on a frame, said frame further having a push plate telescopically mounted thereon for pushing the noodles down from the side of said conveyor belt, wherein said conveyor belt is ring-shaped and a second electric heating plate is further disposed within the ring of said conveyor belt.

10. The honey suppository processing system of claim 9, wherein a first clamping plate located between the first rotating roller and the base and a second clamping plate connected with the second rotating roller are fixedly installed on the base, wherein the first clamping plate and the second clamping plate enclose a first material guiding channel, the strip-shaped object enters the space between the first rotating roller, the second rotating roller and the third rotating roller through the first material guiding channel when the second rotating roller is close to the first rotating roller and the third rotating roller, and the suppository-shaped object is thrown out from the space between the second rotating roller and the third rotating roller when the second rotating roller is far away from the first rotating roller and the third rotating roller.

11. A honey suppository processing system as claimed in claim 10, wherein said second nip plate is movably connected to said second rotating roller so that the lower ends of said first nip plate and said second nip plate can be closely attached to each other during the movement of said second nip plate with said second rotating roller, and said first nip plate and said second nip plate define a second material guiding passage.

12. A honey suppository processing system as claimed in claim 11, wherein both ends of said second rotating roller are rotatably connected with a movable plate, one end of said movable plate far from said second rotating roller is hinged with the upper end of said second clamping plate, and the lower end of said second clamping plate is also rotatably connected with a fixedly arranged rotating shaft.

13. A honey suppository processing system as claimed in claim 1 or 2, characterized in that each said forming station is defined by a pressing rotary forming section provided on said first rotary roller, a cutting rotary forming section provided on said second rotary roller and a lifting rotary forming section provided on said third rotary roller.

14. A honey suppository processing system as claimed in claim 13, wherein a first recess is provided between two adjacent pressure applying rotary shaping segments, a protruding wheel capable of being received in said first recess is provided between two adjacent cutting rotary shaping segments, and a second recess capable of being received by said protruding wheel is provided between two adjacent lifting rotary shaping segments; wherein, the both sides of outstanding wheel are the arcwall face and its marginal both sides meet.

15. A honey suppository processing system as claimed in claim 13, wherein said pressure applying rotary forming section, said cutting rotary forming section and said lifting rotary forming section are provided with a plurality of second anti-slip grooves, and a smooth surface is formed between two adjacent second anti-slip grooves.

16. A honey suppository processing system as claimed in claim 14, characterized in that the outer edge of said protruding wheel is further fixedly connected with a serration ring; the sunken both sides of second are outwards protrusion and are provided with arc portion, two one side that the arc portion carried on the back mutually is the cambered surface, the radian of cambered surface with the radian of arcwall face is the same.

17. A honey suppository processing system as claimed in claim 16, wherein the arc length of said arc is less than the arc length of said arc.

18. The honey suppository processing system of claim 9, further comprising a cooling rack for cooling the suppository, wherein the cooling rack is provided with a plurality of layers of conveying plates which reciprocate horizontally and synchronously, wherein the conveying plates at the uppermost layer and the lowermost layer are divided into two ends which extend beyond the cooling rack, and a fan facing downwards is further installed at the upper end of the cooling rack.

19. The honey suppository processing system of claim 18 wherein said housing further comprises an angled exit channel positioned below said third rotatable roller, said exit channel having a lower end that engages a portion of said uppermost conveyor plate that extends beyond said cooling rack.

20. The honey suppository processing system of claim 19, wherein a detachable mesh plate is arranged in the discharging channel and an interlayer space is arranged between the detachable mesh plate and the inner wall of the discharging channel close to one side of the machine base.

21. A honey suppository, characterized in that it is processed by the processing system as claimed in any one of claims 1 to 20, and the shape of the two ends of the honey suppository comprises one or two of a hemisphere, a semi-ellipsoid, an oval, a bullet and a cylinder.

Technical Field

The invention relates to the technical field of suppository processing technologies, and particularly relates to a honey suppository and a processing system thereof.

Background

According to the record of 0107 suppository in the 2020 edition four-part general rule of Chinese pharmacopoeia:

the suppository is prepared by kneading, cold pressing and hot melting. The kneading method is suitable for preparing fat matrix in small quantity; the cold pressing method is suitable for mass production of the fatty matrix suppository; the hot-melt method is suitable for the batch preparation of fat matrix and water-soluble matrix suppository.

The honey suppository is prepared according to a honey decoction prescription recorded in Shang Zhong Jing (treatise on Cold-induced diseases) of Zhang Zhongjing: ' eating Mi Qi He, adding the first flavor, decocting in a copper container with slow fire until it is coagulated into a cerealose shape, stirring it until it is not scorched, and treating it with a pill, twisting it with the hand to make it straight, with a sharp head, as big as a finger, and two cun long. When hot, it works rapidly, and when cold, it is hard. "

In the prior art, the physical properties of the honey suppository are greatly changed along with temperature reduction after the honey is decocted, if the honey suppository is prepared by a hot melting method, the honey suppository can be solidified in a very short time after being led out of a pot into a mould, and the surface of the suppository can have irregular concave-convex defects to cause secondary damage to the anus of a user and the like; in the prior art, the heating of the mould can be adopted so that the honey decoction can not be solidified in a short time, thereby reducing the amount of depression formation, but cannot be avoided. The honey suppository is required to be cooled in time after being formed, however, the cooling of the mold and the honey suppository in the mold in a short time has higher capital cost and higher efficiency cost, namely, the cooling operation is difficult to be carried out in a short time, more importantly, the method needs to reserve a liquid injection port on the mold, and the boiled honey substance is injected into the mold and then has a self-leveling phenomenon at the liquid injection port, so that the honey suppository with two end faces both having radians and a smooth suppository body is difficult to produce;

the cold pressing method cannot be used completely, the decocted honey which is in a liquid state after being decocted has the conditions of higher hardness, brittleness and certain viscosity at normal temperature, however, the cold pressing method needs to be carried out after cooling, so that the problems of immovable pressing, crushing, bonding on a die and the like exist, and finally, the forming fails;

in the prior art, honey suppositories can only be processed by a kneading method, namely, the honey suppositories are manually prepared, boiled honey is properly cooled, then kneaded into strips, cut into multiple sections and kneaded to finally obtain the honey suppositories, but the efficiency is extremely low, the honey suppositories have large difference, and therefore, the honey suppositories are not suitable for being processed in a large batch and the quality of the honey suppositories cannot be guaranteed.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a honey suppository and a processing system thereof, which solve the problems that in the prior art, the surface of the honey suppository is sunken due to a hot melting method to cause secondary damage to a user, the honey suppository with two ends having radians and a smooth suppository body is difficult to produce, and also solve the problems that a kneading method is not suitable for large-scale processing and the quality of the honey suppository cannot be ensured.

According to the embodiment of the invention, the honey suppository processing system comprises a first rotating roller, a second rotating roller and a third rotating roller which are arranged in a self-rotating mode, wherein the first rotating roller and the third rotating roller are fixedly installed up and down, an included angle between a connecting line of axes of the first rotating roller and the third rotating roller and a horizontal plane is an acute angle, the second rotating roller reciprocates on a path close to or far away from the first rotating roller and the third rotating roller, a plurality of forming stations with radian at two ends and variable width are arranged among the first rotating roller, the second rotating roller and the third rotating roller, and strips are cut among the first rotating roller, the second rotating roller and the third rotating roller to form a plurality of bolt-shaped objects with two arc-shaped ends which are contained in each forming station respectively.

In the above embodiment, the honey decoction which is cooled to 40-80 ℃ after being decocted can be kneaded into uniform strips by manual work, and then the strips are placed among the first rotating roller, the second rotating roller and the third rotating roller to be cut and formed, so that the obtained honey suppository has small individual difference, and the two ends of the honey suppository can form arc-shaped structures such as hemispheres, semiellipsoids, ovals, bullet shapes and cylindersOne or two of；

Specifically, when the second rotating roller is slightly far away from the first rotating roller and the third rotating roller, the strip falls between the first rotating roller, the second rotating roller and the third rotating roller, and simultaneously rotates in the opposite direction along with the rotation of the first rotating roller, the second rotating roller and the third rotating roller, and the strip is close to the first rotating roller and the third rotating roller along with the second rotating roller while being transported;

when the distance between the second rotating roller and the first rotating roller and the distance between the second rotating roller and the third rotating roller are the shortest, the strip-shaped object is cut off, and the cut-off materials are respectively positioned in each forming station and continuously rotate reversely along with the rotation of the first rotating roller, the second rotating roller and the third rotating roller so as to form the bolt-shaped object in the forming stations;

after the formation of the plugs, the second rotating roller starts to be far away from the first rotating roller and the third driving roller, in the process, the plugs are continuously transported, and the plugs are thrown out from between the second rotating roller and the third rotating roller when the distance between the second rotating roller and the third rotating roller is larger than the diameter of the plugs.

Further, the first rotating roller, the second rotating roller and the third rotating roller are all arranged in a hollow mode, and first electric heating rods are arranged in the hollow cavity.

Further, the acute angle is 10-80 degrees.

Further, the processing system further comprises a mechanical kneading component for mechanically kneading the decocted material into a column, wherein the mechanical kneading component comprises four rollers, one end of each roller is larger than the other end of each roller, the position of the larger end of each roller is higher than the position of the other end of each roller, the larger end of each roller is separated from the other end of each roller, the smaller end of each roller is gathered, and the material is mechanically kneaded and then extruded out of the column from the end surfaces of the rollers by four rollers.

Furthermore, the mechanical kneading component further comprises a case, the four rollers are installed in the case, second electric heating rods located below all the rollers are further installed in the case, a case door is arranged at the upper end of the case, and a third electric heating rod is further installed in the case door.

Furthermore, the processing system also comprises a reducing assembly for receiving the column after mechanical kneading, wherein the reducing assembly comprises a horizontally arranged bottom plate and a plurality of pairs of reducing wheels which are horizontally and automatically installed on the bottom plate; wherein a plurality of electric heating rings corresponding to the reducing wheels are arranged below the bottom plate.

Further, the processing system further comprises a cutter for cutting off the column; a buffer plate is arranged between the cutter and one end of the bottom plate far away from the roller, and a first electric heating plate is arranged below the buffer plate; the buffer board is close to the one end of cutter still installs at least a pair of leading wheel, still install on the buffer board with the guide block that the cutter is close to, be provided with on the guide block with two the perforation just right of leading wheel.

Furthermore, a plurality of scrapers for scraping the wheel surface of each reducing wheel are further arranged on the bottom plate, the scrapers are arranged on one side, away from the roller, of each reducing wheel in pairs in parallel, and the scrapers are separated from each other.

Further, the processing system also comprises a spill plate which is pressed above each pair of diameter-reducing wheels and each pair of guide wheels and is in sliding contact with the two diameter-reducing wheels or the two guide wheels.

The processing system further comprises a conveyor belt for receiving the strip-shaped objects, the conveyor belt is arranged on a base, a push plate for pushing the strip-shaped objects down from the side face of the conveyor belt is further arranged on the base in a telescopic mode, and the first rotating roller, the second rotating roller and the third rotating roller are arranged on the base and located below the conveyor belt; wherein the conveyer belt is the loop configuration and still be provided with the second electric heating board in the loop configuration.

Further, a first clamping plate located between the first rotating roller and the base and a second clamping plate connected with the second rotating roller are fixedly installed on the base, wherein the first clamping plate and the second clamping plate enclose a first material guide channel, when the second rotating roller is close to the first rotating roller and the third rotating roller, the strips enter the space between the first rotating roller, the second rotating roller and the third rotating roller through the first material guide channel, and when the second rotating roller is far away from the first rotating roller and the third rotating roller, the plugs are thrown out from the space between the second rotating roller and the third rotating roller.

Further, the second clamping plate is movably connected with the second rotating roller so that the lower ends of the first clamping plate and the second clamping plate can be close to each other in the process that the second clamping plate moves along with the second rotating roller, and the first clamping plate and the second clamping plate surround a second material guide channel.

Furthermore, the two ends of the second rotating roller are rotatably connected with a movable plate, one end of the movable plate, which is far away from the second rotating roller, is hinged with the upper end of the second clamping plate, and the lower end of the second clamping plate is rotatably connected with a fixedly arranged rotating shaft.

Furthermore, each forming station is surrounded by a pressing rotary forming section arranged on the first rotating roller, a cutting rotary forming section arranged on the second rotating roller and a lifting rotary forming section arranged on the third rotating roller.

Furthermore, a first recess is formed between every two adjacent pressure applying rotary forming sections, a protruding wheel capable of being contained in the first recess is arranged between every two adjacent cutting rotary forming sections, and a second recess capable of being contained in the protruding wheel is arranged between every two adjacent lifting rotary forming sections; wherein, the both sides of outstanding wheel are the arcwall face and its marginal both sides meet.

Furthermore, the pressing rotary forming section, the cutting rotary forming section and the lifting rotary forming section are provided with a plurality of second anti-skid grooves, and a smooth surface is arranged between every two adjacent second anti-skid grooves.

Furthermore, the outer edge of the protruding wheel is fixedly connected with a sawtooth ring; the sunken both sides of second are outwards protrusion and are provided with arc portion, two one side that the arc portion carried on the back mutually is the cambered surface, the radian of cambered surface with the radian of arcwall face is the same.

Further, the arc length of the arc surface is smaller than that of the arc surface; the cambered surface can also be a slope surface which is tangential to the cambered surface.

Further, the processing system further comprises a cooling frame used for cooling the bolt-shaped objects, wherein a plurality of layers of conveying plates which synchronously and horizontally move in a reciprocating mode are arranged on the cooling frame, the conveying plates which are located on the uppermost layer and the lowermost layer exceed two ends of the cooling frame, and a fan facing downwards is further installed at the upper end of the cooling frame.

Furthermore, an inclined discharging channel is further installed on the machine base and located below the third rotating roller, and the lower end of the discharging channel is connected with the portion, exceeding the cooling rack, of the conveying plate on the uppermost layer.

Furthermore, set up in the discharging channel and to dismantle the mesh board just can dismantle the mesh board with discharging channel is close to be provided with the intermediate layer space between the one side inner wall of frame.

The invention also provides a honey suppository produced by the processing system, wherein the shape of the two ends of the honey suppository comprises one or two of hemispheres, semi-ellipsoids, ovals, bullet heads and cylinders.

Compared with the prior art, the invention has the following beneficial effects:

the processing system provided by the invention can process the honey suppository with radian at two ends, specifically comprises various expression forms such as hemisphere, semi-ellipsoid, oval, bullet shape, cylinder shape and the like, and enriches the types of the honey suppository;

the processed honey suppository has smooth surface, does not have concave-convex defects, and does not cause secondary damage to the anus of a user when in use;

the processing efficiency is greatly improved, the quality control of the honey suppository is improved, the specification error of the honey suppository is small, the weight error of a single particle can be controlled to be +/-0.1 g, and the size error of the single particle can be controlled to be +/-1 mm.

Drawings

FIG. 1 is a first schematic diagram illustrating a positional relationship among a first rotating roller, a second rotating roller and a third rotating roller according to an embodiment of the present invention;

FIG. 2 is a second schematic view showing the positional relationship among the first rotating roller, the second rotating roller and the third rotating roller according to the embodiment of the present invention;

FIG. 3 is a third schematic view showing the positional relationship among the first rotating roller, the second rotating roller and the third rotating roller according to the embodiment of the present invention;

FIG. 4 is a schematic view of the general structure of a part of the assembly (excluding the cooling rack part) according to the embodiment of the invention;

fig. 5 is a schematic view of an internal structure of a chassis according to an embodiment of the present invention;

FIG. 6 is a schematic top view of four rollers according to an embodiment of the present invention;

FIG. 7 is a schematic side view of a diameter reducing wheel according to an embodiment of the present invention;

FIG. 8 is a schematic top view of a diameter reducing wheel according to an embodiment of the present disclosure;

FIG. 9 is a schematic top view of a buffer board according to an embodiment of the present invention;

FIG. 10 is a schematic view of a rolling wheel mounting structure according to an embodiment of the present invention;

FIG. 11 is a schematic top view of the first rotating roller, the second rotating roller and the third rotating roller of the embodiment of the present invention after they are disassembled;

FIG. 12 is a schematic diagram showing the relative position between the protrusion wheel and the sawtooth ring according to the embodiment of the present invention;

FIG. 13 is a schematic view of two states of the arcuate portion of the embodiment of the present invention;

FIG. 14 is a schematic view of the overall structure of a cooling rack according to an embodiment of the present invention;

FIG. 15 is a schematic structural diagram of a connecting rod in accordance with an embodiment of the present invention;

FIG. 16 is a schematic view of a connection between a tapping channel and a mesh plate according to an embodiment of the invention;

FIG. 17 is a schematic view of a portion of a plug according to an embodiment of the present invention;

in the above drawings:

the device comprises a first rotating roller 1, a second rotating roller 2, a third rotating roller 3, a strip 4, a first electric heating rod 5, a roller 6, a bulge 7, a case 8, a second electric heating rod 9, a third electric heating rod 10, a bottom plate 11, a reducing wheel 12, a cutter 13, an electric heating ring 14, a buffer plate 15, a first electric heating plate 16, a guide wheel 17, a guide block 18, a perforation 19, a guide plate 20, an anti-overflow plate 21, a scraper 22, a cutter head 23, a conveyor belt 24, a machine base 25, a push plate 26, a second electric heating plate 27, a first clamping plate 28, a second clamping plate 29, a first guide channel 30, a second guide channel 31, a movable plate 32, a shaft rotating 33, a hinged seat 34, a rotating column 35, a rolling wheel 36, a pressing rotating forming section 37, a cutting rotating forming section 38, a lifting rotating forming section 39, a first recess 40, a protruding wheel 41, a second recess 42, a first anti-skid groove 43, a sawtooth ring 44, an arc-shaped part 45, The cooling rack 46, the conveying plate 47, the fan 48, the motor 49, the support rod 50, the roller 51, the rotating rod 52, the rotating wheel 53, the cam 54, the connecting rod 55, the belt 56, the discharging channel 57, the mesh plate 58, the horizontal part 59, the vertical part 60, the screw 61, the belt pulley 62, the box door 63, the second anti-slip groove 64, the movable mounting plate 65 and the fixed mounting plate 66.

Detailed Description

The technical solution of the present invention is further explained with reference to the drawings and the embodiments.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the invention.

As shown in fig. 1, 2, and 3, the present embodiment provides a honey suppository processing system, which includes a first rotating roller 1, a second rotating roller 2, and a third rotating roller 3, which are all arranged in a self-rotating manner, wherein the first rotating roller 1 and the third rotating roller 3 are fixedly installed in an up-down manner, an included angle between a connecting line of axes of the first rotating roller 1 and the third rotating roller 3 and a horizontal plane is an acute angle, the second rotating roller 2 reciprocates on a path close to or far from the first rotating roller 1 and the third rotating roller 3, as shown in fig. 11, a plurality of forming stations with variable widths and radian at two ends are arranged between the first rotating roller 1, the second rotating roller 2, and the third rotating roller 3, and a strip 4 is cut between the first rotating roller 1, the second rotating roller 2, and the third rotating roller 3 to form a plurality of suppositories with arc-shaped ends respectively accommodated in each forming station.

In the above embodiment, honey boiled and cooled to 40-80 ℃ can be kneaded into uniform strips 4 by manual work, and then the strips 4 are placed among the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3, so that cutting and forming can be performed, the obtained honey suppository has small individual difference, and two ends can form an arc-shaped structure, such as one or two of a hemisphere, a semi-ellipsoid, an oval, a bullet shape and a cylinder shape (refer to the shape of a part of the suppository listed in fig. 17); the horizontal distance between the third rotating roller 3 and the second rotating roller 2 is closer than the horizontal distance between the first rotating roller 1 and the second rotating roller 2, so that the strip 4 can be ensured to fall between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 smoothly, furthermore, the acute angle, namely the angle alpha in the figure 1 can be set within the range of 10-80 degrees, and further can be set within the range of 40-75 degrees, so that the strip 4 can better enter between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3, and especially when the angle alpha is about 60 degrees (such as 55 degrees, 60 degrees and 65 degrees), the position between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 is the most suitable for the strip 4 to enter;

specifically, when the second rotating roller 2 is slightly distant from the first rotating roller 1 and the third rotating roller 3, the strip 4 falls between the first rotating roller 1, the second rotating roller 2, and the third rotating roller 3, while the strip 4 rotates in the opposite direction in accordance with the rotation of the first rotating roller 1, the second rotating roller 2, and the third rotating roller 3, and the strip 4 also approaches the first rotating roller 1 and the third rotating roller 3 together with the second rotating roller 2 while rotating;

when the distance between the second rotating roller 2 and the first rotating roller 1 and the distance between the second rotating roller 3 and the third rotating roller 3 are the shortest, the strip-shaped objects 4 are cut off, and the cut materials are respectively positioned in each forming station and continuously rotate reversely along with the rotation of the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 so as to form a bolt-shaped object in the forming station;

after the formation of the plugs, the second rotating roller 2 starts to be away from the first rotating roller 1 and the third driving roller 3, during which the plugs are continuously transferred and the plugs are thrown out from between the second rotating roller 2 and the third rotating roller 3 when the distance between the second rotating roller 2 and the third rotating roller 3 is greater than the diameter of the plugs.

As shown in fig. 3, in particular, the present embodiment is suitable for processing honey suppositories with a large diameter, specifically, more than 0.7cm, and also suitable for processing honey suppositories with a diameter of less than 0.7cm, but in order to prevent molding failure caused by too fast cooling in the processing process, the first rotating roller 1, the second rotating roller 2, and the third rotating roller 3 are all hollow, and the first electric heating rod 5 is disposed in each hollow cavity, and the first electric heating rod 5 heats the first rotating roller 1, the second rotating roller 2, and the third rotating roller 3, so that the surrounding temperature thereof is increased, thereby realizing the function of heat preservation, wherein the disposed first electric heating rod 5 can be activated according to circumstances, only one of them can be activated when the summer is hot, and all can be activated when the winter is cold.

As shown in fig. 4, 5 and 6, in order to further improve the efficiency of the processing system, the processing system further comprises a mechanical kneading assembly for mechanically kneading the decocted material into a columnar object, the mechanical kneading assembly comprises four rollers 6 of which one end is larger than the other end, the larger end of the four rollers 6 is higher than the other end, the larger end of the four rollers 6 is separated from the other end, and the smaller end of the four rollers 6 is gathered together, and the material is mechanically kneaded by the four rollers 6 and then extruded out from the end surfaces of the four rollers 6 at the smaller end in a columnar object state;

particularly, two of the four rollers 6 are positioned on the upper layer, two of the four rollers 6 are positioned on the lower layer, one large end of the two rollers 6 positioned on the upper layer is separated, the roller surfaces, close to each other, of the two rollers 6 positioned on the lower layer are arranged in parallel, the width between one ends of the two rollers 6 positioned on the upper layer is larger than that between the other ends of the two rollers as seen from a top view (figure 6), the position of one end with a wider distance is higher than that of the other end of the two rollers, honey boiled and cooled to 40-80 ℃ is placed between the four rollers 6 at one large open end during processing, then the four rollers 6 are started to synchronously perform alternation of forward rotation and overturning, the process is used for simulating a manual kneading step, but the processing efficiency is far higher than that of manual processing, and materials (namely the honey) are extruded from one small end (through continuous forward rotation or reverse rotation and gravity of the materials) after mechanical kneading.

As shown in fig. 6, more importantly, the outer wall of the roller 6 in this embodiment is provided with a plurality of protrusions 7, and the protrusions 7 can prevent the material from slipping during the mechanical kneading process; furthermore, the roll surface of the end (i.e. the end with a small diameter) where the four rollers 6 are gathered together is provided with first anti-slip grooves 43, and when the material is extruded out from between the four rollers 6, the first anti-slip grooves 43 can also play a role of anti-slip.

As shown in fig. 4 and 5, further, the mechanical kneading assembly further comprises a cabinet 8, four rollers 6 are mounted in the cabinet 8, in order to prevent the materials from being continuously cooled in the mechanical kneading process, a second electric heating rod 9 positioned below all the rollers 6 is also arranged in the case 8, a case door 63 is arranged at the upper end of the case 8, a third electric heating rod 10 is also arranged in the case door 63, in the process of mechanical kneading, the second electric heating rod 9 and the third electric heating rod 10 respectively heat the upper part and the lower part of the material, so as to increase the temperature in the whole case 8, thereby achieving the purpose of heat preservation, and particularly, the length of the third electric heating rod 10 is smaller than that of the second electric heating rod 9, this allows the third electric heating rod 10 to heat the material mainly at the lower end when heating, this avoids overheating of the material at the upper end by the third electric heating rod 10 being too close.

As shown in fig. 4, 7 and 8, the material after mechanical kneading has a large diameter and often needs to be subjected to diameter reduction treatment, therefore, the processing system also comprises a reducing component for receiving the column after mechanical kneading, the reducing component comprises a bottom plate 11 arranged horizontally and a plurality of pairs of reducing wheels 12 arranged on the bottom plate 11 in a horizontal rotation way, each pair of reducing wheels 12 are arranged side by side, wherein the wheel surface of each reducing wheel 12 is recessed inwards to ensure that a channel for the column to penetrate is arranged between each pair of reducing wheels 12, the diameter of the column is smaller and smaller after passing through a plurality of pairs of reducing wheels 12 (the channel arranged on each pair of reducing wheels 12 is smaller and smaller from one end close to the roller 6 to the other end, so that the column is extruded and thinned to achieve the purpose of reducing the diameter), so as to reach the degree of processing in the next step, and then the strip-shaped objects 4 are obtained after being cut off by the arranged cutting knife 13. Likewise, in order to avoid the cooling of the material during the diameter reduction, a plurality of electric heating coils 14 corresponding to each diameter reduction wheel 12 are also arranged below the bottom plate 11. Wherein, the bottom plate 11 is also provided with a downward sunken rotating groove for accommodating the lower end part of the reducing wheel 12 and realizing rotation, after the lower end part of the reducing wheel 12 is accommodated in the rotating groove, the channel is arranged to be flush with the upper plate surface of the bottom plate 11, and the column does not have a blocking condition in the moving process so as to smoothly enter and pass through the channel; in particular, the electric heating coil 14 is separated from the bottom plate 11, i.e. the electric heating coil 14 is heated by indirect means, which can avoid overheating, resulting in excessive softening of the material.

As shown in fig. 4 and 9, in order to further ensure the smooth operation of the processing system, i.e. to prevent the processing system from generating a disjointing phenomenon (rear cutting forming is intermittent processing, front reducing is continuous processing) in the processing steps before and after the cutting of the material by the cutter 13, a buffer plate 15 is further arranged between the cutter 13 and one end of the bottom plate 11 far away from the roller 6, and the buffer plate 15 is used for buffering the column before cutting, i.e. the column can be bent at the position to adapt to the subsequent intermittent cutting operation.

As shown in fig. 4, 9, and at the same time, in order to prevent the column from cooling at the buffer plate 15, a first electric heating plate 16 is provided below the buffer plate 15; at least one pair of guide wheels 17 is further mounted at one end, close to the cutter 13, of the buffer plate 15, a guide block 18 which is close to the cutter 13 is further mounted on the buffer plate 15, a through hole 19 which is opposite to the two guide wheels 17 is formed in the guide block 18, a channel which is the same as that between the two reducing wheels 12 is also formed between the two guide wheels 17, and the column-shaped object passes through the channel, enters the through hole 19, passes through the through hole 19 and is then cut into strips 4 by the cutter 13; furthermore, in order to make the column accurately enter the through hole 19 after passing through the guide wheel 17, a pair of guide plates 20 surrounding a bell mouth structure are arranged between the guide block 18 and the adjacent pair of guide wheels 17, and the distance between the ends of the two guide plates 20 far away from the through hole 19 is larger than that between the ends of the two guide plates 20 close to the through hole 19, so that the column can more easily enter the space between the two guide plates 20 and then be inserted into the through hole 19.

As shown in fig. 7, 8 and 9, in this embodiment, a gap is left between each pair of diameter-reducing wheels 12 and each pair of guide wheels 17, so as to ensure that no friction exists between them, thereby avoiding metal chips from mixing into the honey suppository, and in particular, in order to prevent the material from being extruded upwards from the upper gap during passing through the channel (the lower gap is the bottom of the channel, i.e. the bottom plate 11, is closed), the processing system further comprises a spill plate 21 which is pressed above each pair of diameter-reducing wheels 12 and each pair of guide wheels 17 and is in sliding contact with both diameter-reducing wheels 12 or both guide wheels 17, the spill plate 21 is pressed above the gap, so that the gap above the channel is closed, i.e. no additional loss of material is caused, and the spill plate 21 is made of wear-resistant and heavy material (e.g. copper), thereby preventing metal chips from being generated.

As shown in fig. 7 and 9, in order to prevent the column from slipping when moving on the bottom plate 11 and the buffer plate 15, the wheel surfaces of the reducing wheel 12 and the guide wheel 17 are provided with recesses, and the recesses make the wheel surfaces of the reducing wheel 12 and the guide wheel 17 unsmooth, so as to avoid slipping;

further, in order to make the column move more smoothly in the reducing and guiding processes, the bottom plate 11 is further provided with a plurality of scrapers which respectively abut against the wheel surface of each reducing wheel 12, the scrapers 22 are arranged side by side in pairs on one side of each reducing wheel 12, which is far away from the roller 6, and the scrapers 22 are separated from each other, similarly, the buffer plate 15 can also be provided with a plurality of scrapers 22 which respectively abut against the wheel surface of each guiding wheel 1, when the reducing wheels 12 and the guiding wheels 17 rotate, the cutter heads 23 of the scrapers 22 respectively abut against the wheel surface, and a channel for the material to pass through is also formed between the two scrapers 22, so that the material can be more easily separated from the reducing wheels 12 and the guiding wheels 17 and enter between the two scrapers 22 to move forwards smoothly when passing through the reducing wheels 12 and the guiding wheels 17, and meanwhile, the scrapers 22 can prevent the material scraps from adhering to the wheel surface.

As shown in fig. 1, 2, 3, 4 and 9, the processing system further comprises a conveyor belt 24 for receiving the strip-shaped objects 4, the conveyor belt 24 is mounted on a base 25, wherein the cutter 13 is also mounted on the base 25, a push plate 26 for pushing the strip-shaped objects 4 down from the side surface of the conveyor belt 24 is also mounted on the base 25 in a telescopic manner, the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 are mounted on the base 25 and positioned below the conveyor belt 24, the column-shaped objects pass through the through hole 19 and move forward along with the movement of the conveyor belt 24, when the column-shaped objects move to the other end part of the conveyor belt 24, the cutter 13 cuts the column-shaped objects to form the strip-shaped objects 4, and the arranged push plate 26 is used for pushing the strip-shaped objects 4 down below the conveyor belt 24; likewise, to prevent the material from cooling, the conveyor belt 24 is of endless configuration and a second electrical heating plate 27 is also provided within the endless configuration.

As shown in fig. 1, 2 and 3, in order to make the strip 4 enter between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 more accurately, a first clamping plate 28 between the first rotating roller 1 and the base 25 and a second clamping plate 29 connected with the second rotating roller 2 are also fixedly installed on the base 25, wherein the first clamping plate 28 and the second clamping plate 29 enclose a first material guiding channel 30, the width of the upper end of the first material guiding channel 30 is larger than that of the lower end thereof and moves along with the second rotating roller 2, and the size of the first material guiding channel 30 is also changed: specifically, the second nip plate 29 and the second rotating roller 2 move together, so that the distance between the first nip plate 28 and the second nip plate 29 can be adjusted;

when the second rotating roller 2 is close to the first rotating roller 1 and the third rotating roller 3, the strip-shaped objects 4 enter among the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 through the first material guide channel 30, and when the second rotating roller 2 is far away from the first rotating roller 1 and the third rotating roller 3, the bolt-shaped objects are thrown out from between the second rotating roller 2 and the third rotating roller 3; specifically, the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 all rotate in a counterclockwise direction, so that the strip 4 (and the formed plug) are driven to rotate clockwise between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3, and the formed plug can be ejected from between the second rotating roller 2 and the third rotating roller 3 under the tendency of counterclockwise rotation.

As shown in fig. 1, 2 and 3, the first material guiding channel 30 is more suitable for processing the honey suppository with a larger diameter, and when the honey suppository with a smaller diameter is processed, the strip 4 may be bent during falling (the strip has a lighter weight, and each part is unevenly stressed due to a longer length during falling, so that the strip is easily bent), so that the shape of the formed honey suppository is changed, and the honey suppository is unqualified, so as to avoid the problem:

in another embodiment, the processing of bee suppositories of smaller size (less than 0.7 cm): the second clamping plate 29 is movably connected with the second rotating roller 2, so that the lower ends of the first clamping plate 28 and the second clamping plate 29 can be close to each other in the moving process of the second clamping plate 29 along with the second rotating roller 2, at the moment, the first clamping plate 28 and the second clamping plate 29 enclose a second material guide channel 31, and the second material guide channel 31 arranged in the way is different from the first material guide channel 30 in that the lower end of the second material guide channel 31 can be temporarily closed, the strip-shaped objects 4 are pushed down into the second material guide channel 31 by the push plate 26 (the lower end is closed, so that the strip-shaped objects do not continuously fall among the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3), when the second rotating roller 2 continuously approaches the first rotating roller 1, the lower end of the second material guide channel 31 is gradually opened, and the strip-shaped objects 4 then fall among the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 to start forming; the second guide passage 31 thus provided provides a certain buffer effect to the thin noodles 4, thereby preventing the noodles 4 from being bent when falling between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3.

As shown in fig. 1, 2, 3 and 10, further, in another embodiment, both ends of the second rotating roller 2 are rotatably connected to a movable plate 32, one end of the movable plate 32 away from the second rotating roller 2 is hinged to the upper end of the second clamping plate 29, the lower end of the second clamping plate 29 is further rotatably connected to a rotating shaft 33 fixedly mounted on the machine base 25, the movable plate 32 is driven to move when the second rotating roller 2 moves, the movable plate 32 drives the upper end of the second clamping plate 29 to move, and the lower end of the second clamping plate 29 rotates 33 relative to the rotating shaft, i.e. the lower end of the second material guiding channel 31 is closed and opened; furthermore, two hinge seats 34 are fixedly mounted on the upper end surface of the movable plate 32, a rotating column 35 which is rotatably connected with the two hinge seats 34 is rotatably connected to the second clamping plate 29, and a rolling wheel 36 which is in rolling contact with the second clamping plate 29 is mounted between the two hinge seats 34 to prevent metal debris caused by collision between the second clamping plate 29 and the movable plate 32;

the two ends of the second rotating roller 2 are rotatably mounted on the pair of movable mounting plates 65, the movable mounting plates 65 are slidably connected with the base 25, meanwhile, the two ends of the first rotating roller 1 and the third rotating roller 3 are rotatably mounted on the pair of fixed mounting plates 66, and the fixed mounting plates 66 are fixedly connected with the base 25, so that the second rotating roller 2 can smoothly move relative to the base 25, namely, the distance among the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 can be adjusted; specifically, the second clamping plate 29 in fig. 1 and 2 is fixedly connected to the movable mounting plate 65, and the movable plate 32 in fig. 3 is fixedly connected to the movable mounting plate 65.

As shown in fig. 1, 2, 3 and 11, each forming station is defined by a pressing rotary forming section 37 arranged on the first rotary roller 1, a cutting rotary forming section 38 arranged on the second rotary roller 2 and a lifting rotary forming section 39 arranged on the third rotary roller 3, wherein, with the rotation of the first rotary roller 1, the second rotary roller 2 and the third rotary roller 3, the pressing rotary forming section 37 and the cutting rotary forming section 38 exert a pressing effect on the material and assist the material to rotate, the lifting rotary forming section 39 provides a lifting effect to cooperate with the pressing rotary forming section 37 and the cutting rotary forming section 38 to rotate the material among the three, and the lifting rotary forming section 39 also plays a role of assisting the material to rotate; specifically, the pressing rotary forming section 37 and the cutting rotary forming section 38 are located at a position higher than the lifting rotary forming section 39, the materials rotating among the three sections gradually taper along with the approach of the distance between the three sections and are finally cut and formed, and when the distance between the cutting rotary forming section 38 and the lifting rotary forming section 39 is pulled to be larger than the diameter of the formed plug-shaped object, the plug-shaped object is ejected from between the cutting rotary forming section 38 and the lifting rotary forming section 39.

As shown in fig. 1, 2, 3 and 11, a first recess 40 is disposed between two adjacent pressing rotary forming sections 37, a protruding wheel 41 capable of being accommodated in the first recess 40 is disposed between two adjacent cutting rotary forming sections 38, a second recess 42 capable of being accommodated by the protruding wheel 41 is disposed between two adjacent lifting rotary forming sections 39, when the first rotary roller 1, the second rotary roller 2 and the third rotary roller 3 are closest to each other, the protruding wheel 41 is respectively accommodated in the first recess 40 and the second recess 42 to cut the strip 4, wherein the first recess 40 and the second recess 42 are always away from each other, so as to avoid metal debris caused by friction between the first rotary roller 1 and the third rotary roller 3; the two sides of the protruding wheel 41 are arc-shaped surfaces, the two sides of the outer edge of the protruding wheel are connected, when the first rotating roller 1, the second rotating roller 2, the third rotating roller 3 and the strip-shaped object 4 rotate, the protruding wheel 41 gradually cuts into the strip-shaped object 4, when the distance between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3 is the shortest, the outer edge of the protruding wheel 41 slightly exceeds the other side of the central line of the strip-shaped object 4, the strip-shaped object 4 is finally cut off along with the rotation of the first rotating roller, the second rotating roller 2 and the third rotating roller 3, the arranged arc-shaped surfaces gradually rub with materials in the rotating process, and finally the end surfaces of the bolt-shaped object form adaptive arc surfaces, namely, the two ends of the honey suppository have radians.

As shown in fig. 1, 2, 3 and 11, in order to prevent the material from slipping between the first rotating roller 1, the second rotating roller 2 and the third rotating roller 3, a plurality of second anti-slip grooves 64 are respectively arranged on the pressing and rotating forming section 37, the cutting and rotating forming section 38 and the lifting and rotating forming section 39, and a smooth surface is arranged between two adjacent second anti-slip grooves 64, wherein the number of the second anti-slip grooves 64 on the pressing and rotating forming section 37 is the largest, the second anti-slip grooves 64 can effectively prevent the material from slipping, and a smooth surface is arranged between adjacent second anti-slip grooves 64 to make the surface of the formed bolt-shaped object smoother, wherein all the second anti-slip grooves 64 are respectively and equidistantly arranged on the corresponding pressing and rotating forming section 37, cutting and rotating forming section 38 and lifting and rotating forming section 39, the second anti-slip grooves 64 on the first rotating roller 1 play a main anti-slip role, and the second rotating roller 2 and the third rotating roller 3 play an auxiliary role, too many second anti-slip grooves 64 provided on the second rotatable roller 2 and the third rotatable roller 3 will affect the smoothness of the surface of the pin, and therefore too many second anti-slip grooves 64 should not be provided on the second rotatable roller 2 and the third rotatable roller 3.

As shown in fig. 11, 12 and 13, in order to cut the bar-shaped object more efficiently, a sawtooth ring 44 is fixedly connected to the outer edge of the protruding wheel 41, and during the rotation process, the sawtooth ring 44 exceeds the other side of the central line of the bar-shaped object 4 to completely cut the bar-shaped object 4; the outside protrusion in second sunken 42 both sides is provided with arc portion 45, and one side that two arc portions 45 carried on the back mutually is the cambered surface, and the radian of cambered surface is the same with the radian of arcwall face, and the cambered surface length that this department set up is less than the length of arcwall face, and arc portion 45 and arcwall face cooperation form relative confined space promptly rotating the in-process (blade of similar electric fan its performance of external observation is continuous circular structure when high-speed rotation), and the material finally forms the bolt form thing that both ends have the radian in this space.

As shown in fig. 11, 12 and 13, further, in another embodiment, the arc length of the arc surface is smaller than that of the arc surface, so that the formation of the bolt-shaped object can be completed, and the arc surface on the arc portion 45 can be a slope surface which is tangential to the arc surface as an alternative;

more importantly, the arcuate surfaces or portions 45 of the present embodiment need only be modified to accommodate the production of corresponding hemispherical, hemi-ellipsoidal, ovoid, bullet and cylindrical end plugs (as shown in fig. 17).

As shown in fig. 4 and 14, in order to rapidly cool the formed plugs to complete the forming, the processing system further includes a cooling rack 46 for cooling the plugs, a plurality of layers of conveying plates 47 are disposed on the cooling rack 46 and synchronously and horizontally reciprocate, wherein the conveying plates 47 at the uppermost layer and the lowermost layer are divided into two ends extending beyond the cooling rack 46, and a fan 48 facing downward is further installed at the upper end of the cooling rack 46. The bolt-shaped objects are guided onto the cooling rack 46 and move on the cooling rack 46 in a zigzag shape along with the movement of the multiple layers of conveying plates 47, so that the bolt-shaped objects can be cooled quickly in the moving process, and meanwhile, the arranged fan 48 blows cold air from top to bottom, so that the cooling efficiency is improved, wherein holes are formed in each layer of conveying plate 47, so that the cold air can pass through the holes and the bolt-shaped objects cannot pass through the holes, furthermore, the arranged conveying plates 47 are all provided with one end higher than the other end (namely, the conveying plates are obliquely arranged), and the outlet ends of the conveying plates 47 are lower than the inlet ends, so that the bolt-shaped objects can move faster while the conveying plates 47 move, and the bolt-shaped objects are prevented from being bonded on the conveying plates 47; in particular, the inclination of the conveyor plates 47 located at the uppermost and lowermost levels is smaller than the inclination of the conveyor plate 47 located at the middle.

As shown in fig. 4, 14 and 15, in particular, a motor 49 is installed on the cooling rack 46, both ends of all the conveying plates 47 are fixedly connected to two pairs of supporting rods 50, the lower ends of all the supporting rods 50 are rotatably installed with rollers 51 in rolling contact with the cooling rack 46, a rotating rod 52 is fixedly connected to one pair of supporting rods 50, a rotating wheel 53 is rotatably mounted in the middle of the rotating rod 52, a cam 54 is rotatably mounted on the cooling frame 46, a connecting rod 55 is rotatably connected between the rotating wheel 53 and the cam 54, the connecting rod 55 is connected to the convex part of the cam 54, a belt pulley 62 is fixedly arranged on the cam 54, a belt 56 is wound between the motor 49 and the belt pulley 62, the cam 54 is driven to rotate by the cooperation of the belt 56 and the belt pulley 62 when the motor 49 rotates, the rotating rod 52 reciprocates through the connecting rod 55 and the rotating wheel 53 by the cam 54, and finally the reciprocating movement of the conveying plate 47 is realized.

As shown in fig. 4 and 14, in order to quickly guide the formed plugs into the cooling rack 46, an inclined discharging channel 57 is further installed on the machine base 25 below the third rotating roller 3, the lower end of the discharging channel 57 is located right above the portion of the uppermost conveying plate 47 exceeding the cooling rack 46 and is connected with the conveying plate 47, and the plugs are thrown out and fall onto the conveying plate 47 through the discharging channel 57 for cooling.

As shown in fig. 4, 14 and 16, further, a detachable mesh plate 58 is arranged in the discharging channel 57, and an interlayer space is arranged between the detachable mesh plate 58 and the inner wall of the discharging channel 57 close to the base 25. The mesh plate 58 is arranged to filter the plug-like objects to a certain extent, so that part of material scraps generated in the forming process enter the interlayer space and are prevented from moving to the cooling rack 46 together with the material; wherein, the discharging channel 57 who sets up has the gradient, and the parallel same gradient that has of inner wall of mesh board 58 and discharging channel 57 for the material is ensured to be screened off on mesh board 58, and the hole on mesh board 58 is also less than the size of bolt form thing, thereby avoids bolt form thing entering intermediate layer space.

As shown in fig. 4, 14 and 16, specifically, a 7-shaped baffle is fixedly connected to one end of the mesh plate 58, the baffle includes a horizontal portion 59 and a vertical portion 60, the vertical portion 60 is connected to the mesh plate 58, and the horizontal portion 59 is tightly attached to the outer wall of the discharging channel 57, so that the mesh plate 58 is connected to the discharging channel 57.

As shown in fig. 4, 14 and 16, a locking member, such as a screw 61, is further disposed between the horizontal portion 59 and the discharging channel 57, so as to fasten the horizontal portion and the discharging channel, and at the same time, the mesh plate 58 is conveniently detached, and the chips in the interlayer space can be led out after detachment.

The heating temperature of the first electric heating rod 5, the second electric heating rod 9, the third electric heating rod 10, the second electric heating plate 27, the electric heating ring 14 and the first electric heating plate 16 in the above embodiment is based on the temperature around the material being 40-65 ℃, so that the material is in a heat preservation state in the whole forming process, and the problem that the material is finally incapable of being formed due to hardening, brittleness, bonding and the like caused by cooling is effectively avoided.

Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.