CN109718694B - Winter cold patch liquid production equipment - Google Patents

Abstract

The invention discloses a winter cold fluid infusion production device, which comprises: the tank body is horizontally clamped with a partition plate, and the partition plate divides the tank body into an upper stirring cavity and a lower cooling cavity; the moving assembly comprises a moving frame and two first air cylinders; the scraping device comprises four groups of scraping assemblies, wherein each group of scraping assemblies comprises three first connecting rods, and the free ends of the first connecting rods are horizontally connected with long-strip-shaped scraping plates; each group of the first discharging assemblies comprises a first sliding chute, a connecting block, a baffle plate and a second air cylinder; each group of locking assemblies comprises an accommodating groove, a second sliding groove, a sliding block and a steel wire rope; and each group of second discharging assemblies respectively comprises a discharging plate and a third air cylinder. According to the invention, materials are effectively prevented from being bonded on the inner side wall of the upper stirring cavity by up-and-down movement of the movable frame and scraping of the scraper, so that the waste of the materials is reduced.

Description

Winter cold patch liquid production equipment

Technical Field

The invention relates to the technical field of cold make-up liquid production equipment. More specifically, the invention relates to a winter cold patch production device.

Background

The cold patching material is a high-tech road patching material, can be used in all weather, is suitable for patching various different types of road surface courses in any weather and environment, such as asphalt concrete roads, cement concrete roads, parking lots and the like, is continuously improved and perfected for many years, is superior to an emulsified asphalt mixture in quality and use, has the characteristics of long storage time, good patching effect and wide application range, and has been widely applied. The cold patching material is formed by stirring cold patching liquid and waste asphalt mixture, and the cold patching liquid is formed by mixing asphalt adhesives, additives and the like. In the cold make-up fluid production process, because the viscidity of cold make-up fluid can lead to the production facility inner wall to remain a lot of materials, cause the waste.

Disclosure of Invention

An object of the present invention is to solve at least the above problems and to provide at least the advantages described later.

Still another object of the present invention is to provide a winter cold patch production apparatus, which effectively prevents materials from being adhered to the inner sidewall of the upper stirring chamber by the up-and-down movement of the movable frame and the scraping of the scraper, thereby reducing the waste of the materials.

To achieve these objects and other advantages in accordance with the purpose of the invention, there is provided a winter cold fluid infusion production apparatus including:

a support;

the tank body is fixedly arranged on the rectangular structure on the support, the horizontal section of the tank body is square, a partition plate is horizontally clamped in the tank body and divides the tank body into an upper stirring cavity and a lower cooling cavity, a discharge hole is formed in the center of the partition plate, a feed inlet is formed in the top of the upper stirring cavity, a discharge outlet is formed in the center of the bottom of the lower cooling cavity, and a heating plate is arranged in the side wall of the upper stirring cavity;

the sealing assembly comprises a sliding cavity and a cover plate which are arranged in the partition plate, the cover plate is arranged in the sliding cavity in a sliding mode, one end of the cover plate is provided with a pull rod, the free end of the pull rod horizontally slides and extends out of the tank body, a fixed block is fixedly arranged at one end of the pull rod, and when the pull rod is moved until the fixed block is abutted against the tank body, the cover plate seals the discharge port;

the moving assembly is arranged in the upper stirring cavity and comprises a moving frame and two first cylinders, the moving frame is of a cuboid structure with an upper opening and a lower opening, the ratio of the height value of the moving frame to the height value of the upper stirring cavity is 3:4, the two first cylinders are symmetrically arranged on the outer side of the top end of the tank body along the vertical axis of the tank body, the output shafts of the first cylinders vertically and hermetically rotate to extend into the upper stirring cavity and are fixedly connected with the top end of the moving frame so as to drive the moving frame to move up and down, four side walls of the moving frame penetrate through long strip-shaped slideways along the height direction, the length of each slideway is slightly smaller than the height value of the moving frame, and the outer side wall of the moving frame is in contact with the side wall of the upper stirring cavity;

the four groups of scraping assemblies respectively penetrate through four slideways and are fixedly arranged on four inner side walls of the upper stirring cavity, each group of scraping assemblies respectively comprises three first connecting rods which are fixedly arranged on the inner side walls of the upper stirring cavity at equal intervals from top to bottom, the three first connecting rods are equally divided into equal parts of the height value of the upper stirring cavity, the free ends of the three first connecting rods slide through the corresponding slideways and are positioned in the movable frame, the free ends of the first connecting rods are horizontally connected with long-strip-shaped scraping plates, the scraping plates are in contact with the inner side walls of the movable frame corresponding to the scraping plates, the length of the scraping plates is slightly smaller than the side length of the bottom end of the movable frame, and when the movable frame moves to the bottom end and is abutted to the partition plate, the first connecting rod positioned at the top is in contact with the upper ends of the slideways;

two groups of first discharging assemblies which are respectively arranged on one opposite side wall of the lower cooling cavity in a one-to-one correspondence manner, each group of discharging assemblies comprises a first sliding chute, a connecting block, a baffle and a second cylinder, the first sliding chute is a long strip-shaped groove formed by the depression of the inner side wall of the lower cooling cavity, the connecting block is a horizontally arranged long strip-shaped structure, the length of the connecting block is equal to the side length of the inner side wall of the lower cooling cavity, the connecting block is in sliding connection with the first sliding chute through a first positioning block, the connecting block is in contact with the corresponding inner side wall of the lower cooling cavity, the vertical length of the first positioning block is smaller than that of the connecting block, the lower end of the first positioning block is flush with the lower end of the connecting block, the connecting block is hinged with the baffle along the length direction of the connecting block, and the length of the baffle is consistent with that of the connecting block, the fixed end of the second cylinder is fixedly connected with the lower surface of the partition plate, an output shaft of the second cylinder is hinged with a second connecting rod, the free end of the second connecting rod is hinged with the upper surface of the baffle plate, when the free ends of the two baffles in the two groups of first discharging assemblies rotate to be abutted against the lower surface of the partition plate, the discharging port is positioned between the two baffles, when the two baffles rotate to be in a horizontal state, the free ends of the two baffles are abutted against each other, and the lower surfaces of the baffles are flush with the lower end of the connecting block;

two groups of locking components which are respectively arranged corresponding to the two groups of discharging components one by one, each group of locking components comprises a holding tank, a second sliding chute, a sliding block and a steel wire rope, the holding tank is arranged in the side wall of the lower cooling cavity and is positioned above the first sliding chute, the notch of the holding tank faces the moving frame, the second sliding chute is arranged in the connecting block and is positioned above the first positioning block, the vertical section of the second sliding chute is U-shaped and is vertical to the side wall of the lower cooling cavity corresponding to the connecting block, the notch of the second sliding chute faces the side wall of the lower cooling cavity corresponding to the second sliding chute, a through hole is arranged at the bottom of the second sliding chute in a penetrating way, the sliding block is arranged in the second sliding chute in a sliding way, the end part of the sliding block, which is close to the through hole, is connected with the steel wire rope, and the free end of the steel wire rope penetrates through the through hole and is fixedly connected with the baffle plate, when the free ends of the two baffle plates are abutted to the partition plate, the free end of the sliding block is positioned in the accommodating groove, and when the free ends of the two baffle plates are abutted to each other, the sliding block is positioned in the second sliding groove;

four groups of second discharging assemblies, wherein each group of second discharging assemblies respectively comprises a discharging plate and a third cylinder, the discharging plate is vertically arranged in the lower cooling cavity, the bottom of the discharging plate is connected with the bottom of the lower cooling cavity in a sliding manner, the top of the discharging plate is flush with the bottom of the first sliding groove, four discharging plates in the four groups of second discharging assemblies are respectively in one-to-one correspondence with and arranged in parallel with four side walls of the lower cooling cavity, two discharging plates which are parallel at will are symmetrically arranged along the vertical axis of the lower cooling cavity, the axis of the discharging plate is vertical to the vertical axis of the lower cooling cavity, the length of two parallel discharging plates in the four discharging plates is equal to the length of the inner side wall of the lower cooling cavity, the length of the other two parallel discharging plates is equal to the diameter of the discharging port, the third cylinder is arranged outside the tank body, and the output shaft of the third cylinder can horizontally slide into the lower cooling cavity and is fixedly connected with the discharging plate, when the material is cooled, the discharge plate is respectively contacted with the inner side wall of the lower cooling cavity corresponding to the discharge plate, and when the baffle moves downwards to the lowest position during material discharge, the lower surface of the baffle is contacted with the upper end of the discharge plate.

Preferably, four lateral walls of removal frame are sunken to form four long banding third spouts along the direction of height respectively, the altitude value of third spout slightly is less than the altitude value of removal frame, go up and be equipped with four second locating pieces on four inside walls in stirring chamber respectively, four second locating piece one-to-ones slide and locate in four third spouts, work as the bottom of removal frame with during the baffle butt, the second locating piece with rather than the upper end butt of corresponding third spout, in order to realize the removal frame with go up the inside wall sliding connection in stirring chamber.

Preferably, the lower extreme of slide with the distance between the removal frame bottom is 0.5mm, the upper end of slide with the distance between the removal frame top is 0.5 mm.

Preferably, through holes are formed in four side walls of the lower cooling cavity in a penetrating mode, the diameter of each through hole is slightly larger than that of the output shaft of the corresponding third cylinder, the output shafts of the four third cylinders respectively penetrate through the four through holes in a one-to-one correspondence mode, and therefore the third cylinders can be connected with the side walls of the lower cooling cavity in a sliding mode.

Preferably, the bottom of lower cooling chamber is sunken to form two fourth spouts, and two fourth spouts set up perpendicularly, and the line of two fourth spouts passes the center of lower cooling chamber bottom, the length of fourth spout with the length of lower cooling intracavity lateral wall equals, the flitch with the fourth spout passes through third locating piece sliding connection, in order to realize the flitch with the sliding connection of lower cooling chamber bottom.

Preferably, the method further comprises the following steps: the stirrer is arranged in the upper stirring cavity.

The invention at least comprises the following beneficial effects:

firstly, the cold-patch liquid production equipment provided by the invention not only effectively avoids materials from being bonded on the inner side wall of the upper stirring cavity, reduces the waste of the materials, improves the quality of cold-patch liquid, but also can prolong the service time of the cold-patch liquid production equipment through the up-and-down movement of the movable frame and the scraping of the scraper.

Secondly, arranging a sealing assembly, driving the cover plate to move in the sliding cavity through the movement of the pull rod, and further controlling the opening/closing of the discharging, so that the upper stirring cavity is communicated with the lower cooling cavity; through setting up the hot plate, realize the heating to last stirring chamber.

Third, set up and remove subassembly and four groups and scrape the material subassembly, it is on the one hand relative through setting up go up the removal frame that the stirring intracavity lateral wall reciprocated, can realize to bond under the material of last stirring intracavity lateral wall is scraped, this kind of setting not only can avoid the material extravagant, can improve the degree of consistency and the quality of material moreover, and on the other hand can realize hanging down at the material that removes the frame inside wall through setting up the scraper blade, simultaneously, realizes removing reciprocating of frame through setting up first cylinder, through the lateral wall that removes the frame with the inside wall contact of going up the stirring chamber can avoid the material to get into and remove between frame and the last stirring chamber, reduces the waste of material.

Fourthly, two groups of first discharging assemblies are arranged, and the baffle plate is rotated and moved up and down by arranging a second cylinder; the baffle is hinged with the connecting block, so that on one hand, the free end of the baffle is abutted against the baffle, the second cylinder is prevented from contacting with the material, on the other hand, the baffle is in a horizontal state, the baffle keeps in the horizontal state and continuously moves downwards under the action of the second cylinder, the material in the lower cooling cavity moves downwards through the baffle, the material discharging time is shortened, and the working efficiency is improved; the second sliding groove and the second positioning block are arranged to realize the up-and-down movement of the connecting block.

And fifthly, two groups of locking assemblies are arranged, when the sliding block is positioned in the accommodating groove, the connecting block is fixed, when the baffle rotates to a horizontal state gradually from an inclined state, the sliding block moves to the second sliding groove from the accommodating groove, so that the connecting block and the inner side wall of the lower cooling cavity can move relatively, the baffle can keep the horizontal state to move continuously downwards, and material discharge is realized.

Sixth, set up the second and arrange the material subassembly, this kind of residue that can reduce down the material in the cooling chamber on the one hand improves the utilization ratio of material, and on the other hand is compared and is established to invert the round platform form in current cold patch liquid production facility lower extreme, and this kind of setting not only can accelerate material discharge, can will remain in the material of baffle lower surface through longer row flitch in addition and scrape down, scrapes down through the material of shorter row flitch on with longer row flitch, reduces the material and in the internal residue of jar, simultaneously, through setting up the third cylinder in order to drive arrange the removal of flitch.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

FIG. 1 is a schematic structural diagram of a winter cold patch production device according to one embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a winter cold patch production device for cooling materials according to one embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a winter cold patch production device for discharging in accordance with one embodiment of the present invention;

FIG. 4 is a schematic structural view of a closure assembly according to one embodiment of the present invention;

FIG. 5 is a schematic structural view of the upper stirring chamber according to one embodiment of the present invention;

fig. 6 is a schematic structural diagram of one sidewall of the moving frame according to one embodiment of the present invention.

FIG. 7 is an enlarged view of A in FIG. 1;

FIG. 8 is an enlarged view of B in FIG. 2;

fig. 9 is a schematic structural diagram of a connecting block according to one embodiment of the present invention;

fig. 10 is a horizontal cross-sectional view of the second discharging assembly according to one embodiment of the present invention.

Detailed Description

The present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the invention by referring to the description text.

It should be noted that in the description of the present invention, the terms "upper", "lower", "inside", "outside", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, and do not indicate or imply that the referred device or element 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.

As shown in fig. 1 to 10, the present invention provides a winter cold patch production apparatus, comprising:

a bracket 3;

the tank body 1 is of a rectangular structure and is fixedly arranged on the support 3 (along the vertical axis direction), the horizontal section of the tank body 1 is square, a partition plate 5 is horizontally clamped in the tank body 1, the tank body 1 is divided into an upper stirring cavity and a lower cooling cavity by the partition plate 5, a discharge hole 501 is formed in the center of the partition plate 5, a feed inlet 101 is formed in the top of the upper stirring cavity, a discharge outlet 102 is formed in the center of the bottom of the lower cooling cavity, and a heating plate 104 is arranged in the side wall (with a certain thickness) of the upper stirring cavity to heat materials in the upper stirring cavity;

a closed component which comprises a sliding cavity 502 arranged in the clapboard 5 and a cover plate 503, wherein the cover plate 503 is arranged in the sliding cavity 502 in a sliding way, a pull rod 504 is arranged at one end of the cover plate 503, a free end of the pull rod 504 extends out of the tank body 1 in a horizontal sliding manner, a fixed block 505 is fixedly arranged at one end of the pull rod 504 (specifically, a first positioning hole is arranged on the side wall of the sliding cavity 502 in a penetrating manner, a second positioning hole is arranged on the side wall of the tank body 1 in a penetrating manner, the diameters of the first positioning hole and the second positioning hole are slightly larger than the diameter of the pull rod 504 so as to realize that the free end of the pull rod 504 extends out of the tank body 1 in a horizontal sliding manner), and when the pull rod 504 is moved until the fixed block 505 is abutted against the tank body 1, the cover plate 503 seals the discharge opening 501, and when the fixed block 505 is far away from the tank body 1, the upper stirring cavity is communicated with the lower cooling cavity;

the moving assembly is arranged in the upper stirring cavity and comprises a moving frame 401 and two first cylinders, the moving frame 401 (the horizontal section of the moving frame 401 is square) is of a cuboid structure with an upper opening and a lower opening, the ratio of the height value of the moving frame 401 (the height value of the moving frame 401 is the vertical length of the side wall of the moving frame 401) to the height value of the upper stirring cavity (the height value of the upper stirring cavity is the vertical length of the upper stirring cavity) is 3:4, the two first cylinders are symmetrically arranged on the outer side of the top end of the tank body 1 (the first cylinders are arranged outside the tank body 1) along the vertical axis of the tank body 1, the output shafts of the first cylinders vertically and hermetically rotate to extend into the upper stirring cavity and are fixedly connected with the top end of the moving frame 401 so as to drive the moving frame 401 to move up and down, wherein the four side walls of the moving frame 401 are provided with long strip-shaped slideways 406 in a penetrating mode along the height direction, the (vertical) length of the slide 406 is slightly smaller than the height value of the moving frame 401, and the outer side wall of the moving frame 401 is in contact with the side wall of the upper stirring cavity so as to prevent materials from entering between the moving frame 401 and the upper stirring cavity;

four groups of scraping components, wherein the four groups of scraping components respectively penetrate through four slideways 406 and are fixedly arranged on four inner side walls of the upper stirring cavity, each group of scraping components comprises three first connecting rods 405 which are fixedly arranged on the inner side walls of the upper stirring cavity at equal intervals from top to bottom, the three first connecting rods 405 equally divide the height value of the upper stirring cavity, the free ends of the three first connecting rods 405 all slide through the corresponding slideways 406 and are positioned in the movable frame 401 (specifically, the diameter of the first connecting rods 405 is slightly smaller than the width of the slideways 406), the free ends of the first connecting rods 405 are horizontally connected with long-strip-shaped scraping plates 404, and the scraping plates 404 are in contact with the corresponding inner side walls of the movable frame 401, so that the length of the scraping plates 404 remained on the inner side walls of the movable frame 401 is prevented from being slightly smaller than the side length of the bottom end of the movable frame 401, when the movable frame 401 moves to the bottom end and is abutted to the partition plates 5, the uppermost first connecting rod 405 is in contact with the upper end of the slide 406;

two sets of first row's material subassemblies, two sets of first row's material subassemblies are located respectively one-to-one on one of them relative lateral wall of lower cooling chamber, every group row's material subassembly all includes first spout 609, connecting block 603, baffle 601, second cylinder 602, first spout 609 is the rectangular form recess that the inside wall of lower cooling chamber was sunken to be formed, connecting block 603 is the rectangular form structure of level setting, and length with the length of side of the inside wall of lower cooling chamber equals, connecting block 603 through first locating piece 604 with first spout 609 sliding connection, just connecting block 603 contacts with the inside wall of the lower cooling chamber rather than corresponding, the vertical length of first locating piece 604 is less than the vertical length of connecting block 603, connecting block 603 articulates along its length direction baffle 601, the length of baffle 601 with the length of connecting block 603 is unanimous (namely baffle 601 with the perpendicular two limits of connecting block 603 all with the inside wall of lower cooling chamber connects the inside wall When the two baffles 601 are in a horizontal state, the material is completely sealed below the baffles 601), the fixed end of the second cylinder 602 is fixedly connected with the lower surface of the partition plate 5, the output shaft of the second cylinder 602 is hinged with a second connecting rod, the free end of the second connecting rod is hinged with the upper surface of the baffles 601, when the free ends of the two baffles 601 in the two groups of first discharging assemblies rotate to be abutted against the lower surface of the partition plate 5, the discharging port 501 is positioned between the two baffles 601, and when the two baffles 601 rotate to be in a horizontal state, the free ends of the two baffles 601 are abutted against each other;

two groups of locking components which are respectively arranged corresponding to the two groups of discharging components one by one, each group of locking components comprises a holding groove 607, a second sliding groove 605, a sliding block 606 and a steel wire rope 608, the holding groove 607 is arranged in the side wall of the lower cooling cavity and is positioned above the first sliding groove 609 (the holding groove 607 is used for holding the sliding block 606), the notch of the holding groove 607 faces to the movable frame 401, the second sliding groove 605 is arranged in the connecting block 603 and is positioned above the first positioning block 604, the vertical section of the second sliding groove 605 is U-shaped and is vertical to the side wall of the lower cooling cavity corresponding to the connecting block 603, the notch of the second sliding groove 605 faces to the side wall of the lower cooling cavity corresponding to the second sliding groove 605, a through hole is arranged at the bottom of the second sliding groove 605 in a penetrating way, and the sliding block 606 is arranged in the second sliding groove 605 in a sliding way, the end part of the sliding block 606 close to the through hole is connected with the steel wire rope 608, the free end of the steel wire rope 608 passes through the through hole in a sliding manner and is fixedly connected with the baffle plate 601 (specifically, the inner diameter of the through hole is slightly larger than the diameter of the steel wire rope 608), when the free ends of the two baffle plates 601 are abutted against the partition plate 5, the free end of the sliding block 606 is positioned in the accommodating groove 607, and when the free ends of the two baffle plates 601 are abutted against, the sliding block 606 is positioned in the second sliding groove 605;

four groups of second discharging assemblies, each group of second discharging assemblies respectively comprises a discharging plate 701 and a third cylinder 702, the discharging plates 701 are vertically arranged in the lower cooling cavity, the bottoms of the discharging plates 701 are in sliding connection with the bottom of the lower cooling cavity, the tops of the discharging plates 701 are flush with the bottom end of the first chute 609, four discharging plates 701 in the four groups of second discharging assemblies are respectively in one-to-one correspondence and parallel arrangement with four side walls of the lower cooling cavity, any two parallel discharging plates 701 are symmetrically arranged along the vertical axis of the lower cooling cavity, the axis of each discharging plate 701 is vertical to the vertical axis of the lower cooling cavity, the length of two parallel discharging plates 701 in the four discharging plates 701 is equal to the length of the inner side wall of the lower cooling cavity, the length of the other two parallel discharging plates 701 is equal to the diameter of the discharge hole 102, and the third cylinder 702 is arranged outside the tank body 1, and the output shaft of the third cylinder 702 horizontally and slidably extends into the lower cooling cavity and is fixedly connected with the discharge plate 701, the discharge plate 701 is respectively contacted with the inner side wall of the corresponding lower cooling cavity when the material is cooled, and when the baffle 601 moves downwards to the lowest position (the lowest position is that the first positioning block 604 is contacted with the lower end of the first chute 609) during the material discharge, the lower surface of the baffle 601 is contacted with the upper end of the discharge plate 701.

In the technical scheme, the maximum capacity of materials in the lower cooling cavity is that the top of the materials is flush with the bottom end of the connecting block 603, the discharge port 102 is specifically provided with a box door capable of being opened and closed, before the lower cooling cavity is used, the second cylinder 602 is started to enable the second positioning block 403 to move to abut against the upper end of the first chute 609, the baffle 601 rotates from a horizontal state until the free end of the baffle 601 abuts against the partition plate 5, one end of the sliding block 606 is positioned in the accommodating groove 607, the pull rod 504 is moved to enable the cover plate 503 to seal the discharge port 501, the box door seals the discharge port 102, when the lower cooling cavity is used, the materials are added into the upper stirring cavity from the feed port 101, the first cylinder is started, the moving frame 401 moves up and down relative to the inner side wall of the upper stirring cavity to scrape the materials adhered to the inner side wall of the upper stirring cavity, and the materials on the inner side wall of the moving frame 401 are scraped through the scraper 404, after the heating is finished, the second cylinder 602 is started until the free ends of the two baffle plates 601 are abutted against the partition plate 5, then the pull rod 504 is moved until the discharge opening 501 is in an open state, the materials enter the lower cooling chamber and the material guide chamber from the upper stirring chamber, after the materials are cooled, the box door is opened, the second cylinder 602 is started, the baffle 601 rotates to a horizontal state, the slide block 606 is located in the second sliding chute 605, the baffle 601 moves downwards continuously, the material is discharged from the discharge hole 102, when the baffle 601 moves to the lowest position, the third cylinder 702 connected to the longer discharge plate 701 is turned on, both longer discharge plates 701 move toward the discharge port 102, when the longer discharge plate 701 contacts the shorter two discharge plates 701, the third cylinder 702 connected to the shorter discharge plate 701 is turned on, and the shorter two discharge plates 701 move toward the discharge port 102 until the discharge of the material is completed. By adopting the technical scheme, the cold patch production equipment disclosed by the invention not only effectively avoids materials from being adhered to the inner side wall of the upper stirring cavity, reduces the waste of the materials and improves the quality of cold patch, but also can prolong the service time of the cold patch production equipment through the up-and-down movement of the movable frame 401 and the scraping of the scraper 404; a sealing component is arranged, the cover plate 503 is driven to move in the sliding cavity 502 through the movement of the pull rod 504, and the opening/closing of the discharging is further controlled, so that the communication between the upper stirring cavity and the lower cooling cavity is realized; the heating plate 104 is arranged to heat the upper stirring cavity; the material scraping device is characterized in that a moving assembly and four groups of material scraping assemblies are arranged, on one hand, materials adhered to the inner side wall of the upper stirring cavity can be scraped by arranging the moving frame 401 capable of moving up and down relative to the inner side wall of the upper stirring cavity, material waste can be avoided, the uniformity and quality of the materials can be improved, on the other hand, the materials adhered to the inner side wall of the moving frame 401 can be hung by arranging the scraper 404, meanwhile, the moving up and down of the moving frame 401 can be realized by arranging the first air cylinder, and the materials can be prevented from entering between the moving frame 401 and the upper stirring cavity by contacting the outer side wall of the moving frame 401 and the inner side wall of the upper stirring cavity, so that the material waste is reduced; two groups of first discharging assemblies are arranged, the baffle 601 is arranged to rotate and move up and down through the arrangement of the second cylinder 602, the baffle 601 is hinged to the connecting block 603, on one hand, the free end of the baffle 601 is abutted to the partition plate 5, the second cylinder 602 is prevented from contacting with materials, on the other hand, the baffle 601 is in a horizontal state, the baffle 601 keeps moving downwards continuously in the horizontal state under the action of the second cylinder 602, the materials in the lower cooling cavity move downwards through the baffle 601, the discharging time is shortened, and the working efficiency is improved; the connecting block 603 moves up and down by arranging a second sliding chute 605 and a second positioning block 403; two groups of locking components are arranged, when the sliding block 606 is positioned in the accommodating groove 607, the connecting block 603 is fixed, when the baffle 601 rotates gradually from an inclined state to a horizontal state, the sliding block 606 moves from the accommodating groove 607 to the second sliding groove 605, so that the connecting block 603 and the inner side wall of the lower cooling cavity can move relatively, the baffle 601 can keep the horizontal state to move downwards continuously, and material discharge is realized; set up the second and arrange the material subassembly, this kind of residue that can reduce down the interior material of cooling chamber improves the utilization ratio of material on the one hand, and on the other hand compares and establishes to invert the round platform form in current cold makeup liquid production facility lower extreme, and this kind of setting not only can accelerate the material and discharge, can scrape down the material on longer discharge plate 701 through shorter discharge plate 701 in addition, reduces the material in jar internal 1 remaining, simultaneously, through setting up third cylinder 702 in order to drive discharge plate 701's removal.

In another technical scheme, four outer side walls of the moving frame 401 are respectively recessed along the height direction to form four long-strip-shaped third sliding grooves 402, the height value of the third sliding grooves 402 is slightly smaller than that of the moving frame 401, four second positioning blocks 403 are respectively arranged on four inner side walls of the upper stirring cavity, the four second positioning blocks 403 are slidably arranged in the four third sliding grooves 402 in a one-to-one correspondence manner, when the bottom end of the moving frame 401 is abutted to the partition plate 5, the second positioning blocks 403 are abutted to the upper ends of the corresponding third sliding grooves 402, so that the moving frame 401 is slidably connected to the inner side walls of the upper stirring cavity. By adopting the technical scheme, the sliding connection between the movable frame 401 and the inner side wall of the upper cooling cavity is realized through the arrangement.

In another technical scheme, the distance between the lower end of the slide 406 and the bottom end of the movable frame 401 is 0.5mm, and the distance between the upper end of the slide 406 and the top end of the movable frame 401 is 0.5 mm. By adopting the technical scheme, the movable frame 401 can move up and down in the upper stirring cavity conveniently.

In another technical scheme, through holes are formed in all four side walls of the lower cooling cavity in a penetrating mode, the diameter of each through hole is slightly larger than that of the output shaft of the third cylinder 702, the output shafts of the four third cylinders 702 respectively penetrate through the four through holes in a one-to-one correspondence mode, and therefore the third cylinders 702 can be connected with the side walls of the lower cooling cavity in a sliding mode. By adopting the technical scheme, the slidable connection between the third cylinder 702 and the side wall of the lower cooling cavity is realized.

In another technical scheme, the bottom of lower cooling chamber is sunken to form two fourth spouts, and two fourth spouts set up perpendicularly, and the line of two fourth spouts passes the center of lower cooling chamber bottom, the length of fourth spout with the length of lower cooling intracavity lateral wall equals, row flitch 701 with the fourth spout passes through third locating piece sliding connection, in order to realize row flitch 701 with the sliding connection of lower cooling chamber bottom. By adopting the technical scheme, the sliding connection between the discharge plate 701 and the lower cooling cavity is realized.

In another technical solution, the method further comprises: and the stirrer 2 is arranged in the upper stirring cavity. By adopting the technical scheme, the materials are mixed more uniformly, and the quality of the cold fluid infusion is improved.

The number of apparatuses and the scale of the process described herein are intended to simplify the description of the present invention. Applications, modifications and variations of the winter cold fluid infusion production apparatus of the present invention will be apparent to those skilled in the art.

While embodiments of the invention have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims (6)

1. Winter cold patch production facility, its characterized in that includes:

a support;

the tank body is fixedly arranged on the rectangular structure on the support, the horizontal section of the tank body is square, a partition plate is horizontally clamped in the tank body and divides the tank body into an upper stirring cavity and a lower cooling cavity, a discharge hole is formed in the center of the partition plate, a feed inlet is formed in the top of the upper stirring cavity, a discharge outlet is formed in the center of the bottom of the lower cooling cavity, and a heating plate is arranged in the side wall of the upper stirring cavity;

the sealing assembly comprises a sliding cavity and a cover plate which are arranged in the partition plate, the cover plate is arranged in the sliding cavity in a sliding mode, one end of the cover plate is provided with a pull rod, the free end of the pull rod horizontally slides and extends out of the tank body, a fixed block is fixedly arranged at one end of the pull rod, and when the pull rod is moved until the fixed block is abutted against the tank body, the cover plate seals the discharge port;

the moving assembly is arranged in the upper stirring cavity and comprises a moving frame and two first cylinders, the moving frame is of a cuboid structure with an upper opening and a lower opening, the ratio of the height value of the moving frame to the height value of the upper stirring cavity is 3:4, the two first cylinders are symmetrically arranged on the outer side of the top end of the tank body along the vertical axis of the tank body, the output shafts of the first cylinders vertically and hermetically rotate to extend into the upper stirring cavity and are fixedly connected with the top end of the moving frame so as to drive the moving frame to move up and down, four side walls of the moving frame penetrate through long strip-shaped slideways along the height direction, the length of each slideway is slightly smaller than the height value of the moving frame, and the outer side wall of the moving frame is in contact with the side wall of the upper stirring cavity;

the four groups of scraping assemblies respectively penetrate through four slideways and are fixedly arranged on four inner side walls of the upper stirring cavity, each group of scraping assemblies respectively comprises three first connecting rods which are fixedly arranged on the inner side walls of the upper stirring cavity at equal intervals from top to bottom, the three first connecting rods are equally divided into equal parts of the height value of the upper stirring cavity, the free ends of the three first connecting rods slide through the corresponding slideways and are positioned in the movable frame, the free ends of the first connecting rods are horizontally connected with long-strip-shaped scraping plates, the scraping plates are in contact with the inner side walls of the movable frame corresponding to the scraping plates, the length of the scraping plates is slightly smaller than the side length of the bottom end of the movable frame, and when the movable frame moves to the bottom end and is abutted to the partition plate, the first connecting rod positioned at the top is in contact with the upper ends of the slideways;

two groups of first discharging assemblies which are respectively arranged on one opposite side wall of the lower cooling cavity in a one-to-one correspondence manner, each group of discharging assemblies comprises a first sliding chute, a connecting block, a baffle and a second cylinder, the first sliding chute is a long strip-shaped groove formed by the depression of the inner side wall of the lower cooling cavity, the connecting block is a horizontally arranged long strip-shaped structure, the length of the connecting block is equal to the side length of the inner side wall of the lower cooling cavity, the connecting block is in sliding connection with the first sliding chute through a first positioning block, the connecting block is in contact with the corresponding inner side wall of the lower cooling cavity, the vertical length of the first positioning block is smaller than that of the connecting block, the lower end of the first positioning block is flush with the lower end of the connecting block, the connecting block is hinged with the baffle along the length direction of the connecting block, and the length of the baffle is consistent with that of the connecting block, the fixed end of the second cylinder is fixedly connected with the lower surface of the partition plate, an output shaft of the second cylinder is hinged with a second connecting rod, the free end of the second connecting rod is hinged with the upper surface of the baffle plate, when the free ends of the two baffles in the two groups of first discharging assemblies rotate to be abutted against the lower surface of the partition plate, the discharging port is positioned between the two baffles, when the two baffles rotate to be in a horizontal state, the free ends of the two baffles are abutted against each other, and the lower surfaces of the baffles are flush with the lower end of the connecting block;

two groups of locking components which are respectively arranged corresponding to the two groups of discharging components one by one, each group of locking components comprises a holding tank, a second sliding chute, a sliding block and a steel wire rope, the holding tank is arranged in the side wall of the lower cooling cavity and is positioned above the first sliding chute, the notch of the holding tank faces the movable frame, the second sliding chute is arranged in the connecting block and is positioned above the first positioning block, the vertical section of the second sliding chute is U-shaped and is vertical to the side wall of the lower cooling cavity corresponding to the connecting block, the notch of the second sliding chute faces the side wall of the lower cooling cavity corresponding to the second sliding chute, a through hole is arranged at the bottom of the second sliding chute in a penetrating way, the sliding block is arranged in the second sliding chute in a sliding way, the end part of the sliding block close to the through hole is connected with the steel wire rope, and the free end of the steel wire rope passes through the through hole and is fixedly connected with the baffle, when the free ends of the two baffle plates are abutted to the partition plate, the free end of the sliding block is positioned in the accommodating groove, and when the free ends of the two baffle plates are abutted to each other, the sliding block is positioned in the second sliding groove;

four groups of second discharging assemblies, wherein each group of second discharging assemblies respectively comprises a discharging plate and a third cylinder, the discharging plate is vertically arranged in the lower cooling cavity, the bottom of the discharging plate is connected with the bottom of the lower cooling cavity in a sliding manner, the top of the discharging plate is flush with the bottom of the first sliding groove, four discharging plates in the four groups of second discharging assemblies are respectively in one-to-one correspondence with and arranged in parallel with four side walls of the lower cooling cavity, two discharging plates which are parallel at will are symmetrically arranged along the vertical axis of the lower cooling cavity, the axis of the discharging plate is vertical to the vertical axis of the lower cooling cavity, the length of two parallel discharging plates in the four discharging plates is equal to the length of the inner side wall of the lower cooling cavity, the length of the other two parallel discharging plates is equal to the diameter of the discharging port, the third cylinder is arranged outside the tank body, and the output shaft of the third cylinder can horizontally slide into the lower cooling cavity and is fixedly connected with the discharging plate, when the material is cooled, the discharge plate is respectively contacted with the inner side wall of the lower cooling cavity corresponding to the discharge plate, and when the baffle moves downwards to the lowest position during material discharge, the lower surface of the baffle is contacted with the upper end of the discharge plate.

2. The winter cold fluid infusion production device according to claim 1, wherein four outer side walls of the movable frame are respectively recessed in a height direction to form four elongated third sliding grooves, a height value of the third sliding grooves is slightly smaller than a height value of the movable frame, four second positioning blocks are respectively disposed on four inner side walls of the upper stirring chamber, the four second positioning blocks are slidably disposed in the four third sliding grooves in a one-to-one correspondence manner, and when a bottom end of the movable frame abuts against the partition plate, the second positioning blocks abut against upper ends of the corresponding third sliding grooves, so that the movable frame is slidably connected with the inner side walls of the upper stirring chamber.

3. The winter cold fluid infusion production apparatus of claim 1, wherein a distance between a lower end of the slide way and a bottom end of the moving frame is 0.5mm, and a distance between an upper end of the slide way and a top end of the moving frame is 0.5 mm.

4. The winter cold fluid infusion production device according to claim 1, wherein through holes are formed in all four side walls of the lower cooling cavity in a penetrating mode, the diameter of each through hole is slightly larger than that of the output shaft of the third cylinder, and the output shafts of the four third cylinders respectively penetrate through the four through holes in a one-to-one correspondence mode so that the third cylinders can be slidably connected with the side walls of the lower cooling cavity.

5. The winter cold fluid infusion production device according to claim 1, wherein the bottom of the lower cooling chamber is recessed to form two fourth chutes, the two fourth chutes are vertically arranged, a connecting line of the two fourth chutes passes through the center of the bottom of the lower cooling chamber, the length of each fourth chute is equal to that of the inner side wall of the lower cooling chamber, and the discharge plate is slidably connected with the fourth chutes through a third positioning block so as to achieve the sliding connection between the discharge plate and the bottom of the lower cooling chamber.

6. The winter cold fluid infusion production device of claim 1, further comprising: the stirrer is arranged in the upper stirring cavity.

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