CN117962071A - Production equipment for high-compactness soup way bricks - Google Patents

Abstract

The invention discloses production equipment for high-compactness soup way bricks, and aims to provide the production equipment for the high-compactness soup way bricks, which has uniform filling, high compactness and improved production efficiency and product quality. The automatic leveling device comprises a support, wherein the support is movably connected with an upper shaping seat and a lower shaping seat, the support is connected with a shaping shell, the shaping shell is arranged between the upper shaping seat and the lower shaping seat, the lower shaping seat is in scarf joint with one end of the shaping shell and forms a shaping cavity, the support is connected with a quantitative feeding mechanism, a rotating mechanism and a leveling mechanism, the shaping shell and the lower shaping seat are rotationally connected with the support through the rotating mechanism, the quantitative feeding mechanism is matched with the other end of the shaping shell, and the leveling mechanism is connected with the shaping shell. The beneficial effects of the invention are as follows: the compactness is improved; and the production and preparation efficiency is improved.

Description

Production equipment for high-compactness soup way bricks

Technical Field

The invention relates to the technical field of preparation of soup way bricks, in particular to production equipment for high-compactness soup way bricks.

Background

The runner brick (runner brick) is a hollow refractory brick and is usually used at a ladle runner position for circulating molten steel, one end of the runner brick is hollow and is provided with a boss interface communicated with the internal cavity, the other end of the runner brick is sealed, and the end brick body is provided with an opening communicated with the internal cavity; in order to ensure the overall structural strength and fire resistance, the profile steel brick is produced in a die casting mode, namely, small particle materials are filled in a cavity provided with a core and are die-cast and formed by a hydraulic press; because the end part of the material filling machine is provided with the boss interface, operators are required to manually fill the material in the boss interface cavity when filling the material, the production efficiency is low, the production quality is difficult to ensure, the manual material filling in the boss interface cavity is required to be carried out by higher work, and the filling tightness directly influences whether the boss interface of the formed product is defective or not and the service life of the boss interface; in addition, the existing production mode is low in automation degree, and labor intensity of operators is high.

Chinese patent grant bulletin number: the utility model discloses a device for preparing a steel brick, which comprises a hydraulic press and is characterized in that the CN 218428975U is an authorized bulletin day 2023, 02 and 03: also comprises a forming device; the forming device is arranged on the table top of the hydraulic machine working platform and comprises a bottom plate, a left baffle plate, a right baffle plate, a front baffle plate and a rear baffle plate, supporting legs are arranged between the two sides of the bottom plate and the hydraulic machine working platform, and the top of the bottom plate is jointly enclosed into a first cavity corresponding to the length and the width of the steel brick through the left baffle plate, the right baffle plate, the front baffle plate and the rear baffle plate; the right side of the bottom plate corresponding to the rear end of the right baffle is provided with a right-angle baffle, and the rear end of the right baffle, the right-angle baffle and the rear baffle jointly enclose a second cavity; the rear ends of the left baffle, the right baffle and the right baffle are provided with sliding grooves which are correspondingly matched with the rear baffle; one end of the bottom plate corresponding to the rear baffle is provided with a telescopic cylinder I for driving the rear baffle to slide. The technical scheme has the defects that 1, the compression of the forming cavity is unidirectional compression, so that the efficiency and the stress are reduced, and the compactness and the production efficiency of a brick body are affected; 2. after filling, the uniform filling in the cavity is difficult to maintain, so that the pressing uniformity is reduced, and the compactness of the brick body is further influenced.

To sum up: the compactness of the brick molding and the low uniformity of the filling material affect the production efficiency and quality.

Disclosure of Invention

The invention provides production equipment for the high-compactness runner brick, which is uniform in filling, high in compactness and capable of improving the production efficiency and the product quality, and aims to overcome the defects that the compactness of the runner brick in molding and the uniformity of filling are low and the production efficiency and the product quality are affected in the prior art.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

The utility model provides a production facility for high compactness hot water way brick, which comprises a bracket, support removal is connected with shaping seat and lower shaping seat, leg joint has the shaping shell, the shaping shell is arranged in between last shaping seat and the lower shaping seat, lower shaping seat and the one end scarf joint of shaping shell just form the die cavity, leg joint has ration feeding mechanism, rotary mechanism and leveling mechanism, shaping shell and lower shaping seat are connected through rotary mechanism and support rotation, ration feeding mechanism and the other end looks adaptation of shaping shell, leveling mechanism is connected with the shaping shell.

The upper end of the bracket is movably connected with an upper shaping seat, the lower end of the bracket is movably connected with a lower shaping seat, the middle of the bracket is connected with a shaping shell, the upper shaping seat and the lower shaping seat are shaping dies of two side surfaces of a brick body, the shaping shell is a shaping die of the side surface of the brick body, the end surfaces of the upper shaping seat and the lower shaping seat are matched so as to be capable of being butted when connecting two brick bodies, the upper shaping seat is arranged above the shaping shell so as to be convenient for filling the shaping shell in advance, the lower shaping seat is arranged at the lower end of an inner cavity of the shaping shell, a columnar structure is connected in the middle of the lower shaping seat relative to the lower shaping seat so as to enable the brick body to flow through a steel channel, correspondingly, a yielding groove which is opposite to the columnar structure is arranged on the upper shaping seat so as to be more tightly pressed when the filling is pressed, and the lower shaping seat is used for piling up under the action of gravity of the filling through the lower shaping seat, namely, the two ends of shaping are used for realizing shaping are pressed, and the filling is more efficient and compact, and the compactness is improved; the support is connected with a rotating mechanism and a leveling mechanism, the shaping shell rotates through the rotating mechanism together with the lower shaping seat, so that materials are filled in the rotating shaping cavity, and the filling efficiency of the shaping cavity is improved; the shaping shell enables the filler of the shaping cavity to be tidied through the leveling mechanism, enables the overall cloth in the shaping cavity to be uniform, and further enhances the shaping compactness. The effect of improving compactness and preparation efficiency is achieved.

Preferably, the support is provided with an upper hydraulic press and a lower hydraulic press, the upper hydraulic press is connected with an upper pressing rod, the lower hydraulic press is connected with a lower pressing rod, the upper pressing rod is connected with an upper shaping seat, the lower pressing rod is arranged opposite to the lower shaping seat, the support is provided with a support rod, one end of the support rod is connected with the support, the other end of the support rod is connected with an upper orientation ring and a lower orientation ring, the upper pressing rod is connected with the upper orientation ring in an inserting mode, and the lower pressing rod is connected with the lower orientation ring in an inserting mode. The upper end of the support is provided with an upper hydraulic press which is used for being connected with an upper pressing rod, the lower end of the support is connected with a lower hydraulic press which is used for being connected with a lower pressing rod, the upper pressing rod is connected with an upper shaping seat so as to support and move the upper shaping seat, the lower pressing rod is connected with a lower shaping seat so as to push the lower shaping seat, an upper directional ring is fixed on the support through a supporting rod so as to enable the movement orientation of the upper pressing rod to be stable, and a lower directional ring is fixed on the support through the supporting rod so as to enable the movement orientation of the lower pressing rod to be stable. The effect of improving the moving stability of the structure is achieved.

Preferably, the quantitative feeding mechanism comprises a storage bin and a feeding plate, wherein the support is connected with a support frame, the storage bin is connected with the support frame, one end of the feeding plate is arranged below the storage bin, the other end of the feeding plate is arranged above the fixed cavity, the support is connected with a telescopic mechanism I, the feeding plate is connected with a movable seat, the movable seat is connected with the telescopic mechanism I, and the feeding plate is movably connected with the support through the telescopic mechanism I. The storage silo in the ration feeding mechanism is through on the support frame on the support to make the storage silo place steadily, the delivery sheet passes through telescopic machanism one and removes the connection of seat, makes the delivery sheet can remove on the support, and the top of deciding the die cavity is arranged in to the one end of delivery sheet simultaneously, and the storage silo below is arranged in to the other end, in order to make the material of storage silo pass through the delivery sheet and get into and decide the die cavity and pack, makes the pay-off accurate target in place through the removal of delivery sheet simultaneously accessible step down prevent the structural movement who influences the upper shaping seat. The effects of improving the structure matching smoothness and the production efficiency are achieved.

Preferably, the support frame is provided with a quantitative box, the quantitative box is arranged between the storage bin and the feeding plate, the quantitative box is connected with a fixed rod, the support frame is connected with a first elastic mechanism, the first elastic mechanism is connected with the quantitative box, the first elastic mechanism is sleeved with the fixed rod, the quantitative box is connected with a first quantitative ruler, the support frame is connected with a second quantitative ruler, and the first quantitative ruler is in sliding connection with the second quantitative ruler. The quantitative box is arranged below the storage bin and above the feeding plate, so that discharging and quantifying are performed through the quantitative box, and filling materials are quantified, wherein the quantitative box is supported and reset through the elastic mechanism I on the support frame, the stability is improved through the deformation of the elastic mechanism I on the quantitative box, the quantitative rule I is connected to the quantitative box, the quantitative rule II is connected to the support frame, and visual quantification is achieved through relative sliding of the quantitative rule I and the quantitative rule II through material entering of the quantitative box. The effects of improving the packing and production efficiency and enabling the production density to be more accurate by automatic control and quantification are achieved.

Preferably, the storage bin and the quantitative box are connected with a fixed block, a second telescopic mechanism and a material guide plate, the fixed block is connected with the second telescopic mechanism, the second telescopic mechanism is connected with a sealing cover, the cover plate is movably connected through the second telescopic mechanism, and the material guide plate is arranged opposite to the sealing cover. The lower bottom of storage silo and ration case all is equipped with the discharge gate, be equipped with the feed inlet on the ration case, the feed inlet of ration case and the upper and lower relative arrangement of the discharge gate of storage silo, the discharge gate of ration case and the upper end relative arrangement of charge-in board, the fixing base has all been connected to discharge gate department, the fixed block is through connecting telescopic machanism two, make telescopic machanism two install stably, be connected the closing cap on the telescopic machanism two, be used for removing the closing cap and make to seal and open the discharge gate, realize the ejection of compact automatic high efficiency, all be connected the stock guide on storage silo and the ration case in addition, directional ejection of compact is carried out through the stock guide in the messenger ejection of compact, prevent that the material from falling out and not used for the filler. The effects of further improving the packing precision and automation are achieved.

Preferably, the leveling mechanism comprises a buffer frame and a fixed ring, the support is connected with a vibration mechanism, the vibration mechanism is movably connected with the shaping shell, the fixed ring is connected with the support, one end of the buffer frame is slidably connected with the fixed ring, the shaping shell is sleeved with a mounting ring, the mounting ring is provided with a clamping groove, the other end of the buffer frame is connected with the clamping groove, and the buffer frame is elastically connected with the shaping shell. The fixed ring is connected on the support in the leveling mechanism, and the vibration mechanism is connected on the support and used for striking and vibrating the shaping shell (lower shaping seat) so as to level the material in the uniform shaping cavity, and the buffer frame is used for buffering the vibration mechanism through elastic connection, so that the shaping shell can be moved by the vibration mechanism for a small distance and can be kept stable when not vibrated so as to facilitate filling and pressing. The buffer frame can rotate on the fixed ring to adapt to the rotation packing of the shaping shell, and the mounting ring is fixedly sleeved on the shaping shell, so that the buffer frame is movably connected in a clamping groove of the mounting ring, and the buffer frame is convenient to assemble and disassemble, and is especially maintained after elastic fatigue. The effects of improving leveling automation and efficiency, realizing smooth structure operation, facilitating assembly and maintenance and guaranteeing the service life of the structure are achieved.

Preferably, the buffer frame comprises a pulley, a connecting rod, a movable rod and a second elastic mechanism, wherein a guide sliding rail is arranged on the fixed ring, the pulley is in rolling connection with the guide sliding rail, one end of the connecting rod is connected with the pulley, the other end of the connecting rod is provided with a movable groove, one end of the movable rod is spliced with the movable groove, the other end of the movable rod is spliced with the clamping groove, the second elastic mechanism is sleeved with the movable rod, one end of the second elastic mechanism is connected with the connecting rod, and the other end of the second elastic mechanism is connected with the mounting ring. The pulley roll connection is on the direction slide rail in the buffer frame, makes the connecting rod smoothly rotate on solid fixed ring, and the movable rod is pegged graft and cup joints on the movable rod with the connecting rod, makes through elastic mechanism two movable rods can remove in the movable tank, and then cooperates vibration mechanism's activity, makes the design shell stable have structural flexibility simultaneously. The effects of improving the structural connection strength and the operation smoothness are achieved.

Preferably, the support is provided with a stabilizing seat, the stabilizing seat comprises a support plate and a limiting ring, the support plate is connected with the support, the shaping shell is in sliding connection with the support plate, a yielding hole is formed in the support plate, the aperture of the yielding hole is larger than that of the lower pressing rod, the aperture of the yielding hole is smaller than the outer diameter of the shaping shell, the limiting ring is connected with the support plate, and the limiting ring is sleeved with the shaping shell and leaves a gap. The support is connected with a stabilizing seat for supporting the shaping shell so as to lighten the buffer frame from overlarge gravity and prevent the structure from breaking. Wherein the backup pad is fixed on the support, the interior circle of backup pad is set up to the hole of stepping down in order to push down the shaping seat in order to push down the hole of stepping down, and the aperture of the hole of stepping down is less than the shaping shell simultaneously, prevents that the shaping shell from stepping down the hole and falling out, and the backup pad is connected with the spacing ring, further restricts the movable range of shaping shell through spacing ring and shaping shell surface to further stabilize shaping shell and flattening operation. The effect of improving the structural connection and the operation stability is achieved.

Preferably, the rotating mechanism comprises a rotating disc, a rotating ring and a rotating mechanism, the rotating mechanism is connected with the supporting plate, the rotating disc is connected with the rotating mechanism, the rotating ring is sleeved with the shaping shell, the rotating ring is provided with a first tooth slot, the rotating disc is provided with a second tooth slot matched with the first tooth slot, and the rotating ring is meshed with the rotating disc. The rotary mechanism is connected to the support plate, the rotary disc is connected with the rotary mechanism to provide rotary power for the rotary disc, the rotary ring is fixedly sleeved outside the shaping shell, the shaping shell can rotate through engagement of the rotary disc and the rotary ring, and then the annular shaping cavity is filled in a rotatable mode, and automatic stable filling is improved. The effects of improving structural installation and operation stability, and improving filling automation and blanking are achieved.

Preferably, the support is connected with a third telescopic mechanism, the rotating mechanism is connected with the third telescopic mechanism, the supporting plate is provided with a sliding groove, and the rotating mechanism is in sliding connection with the sliding groove through the third telescopic mechanism. And the support is provided with a third telescopic mechanism, the telescopic mechanism is connected to the rotary mechanism and provides power for the rotary mechanism to move in the support plate, the support plate is provided with a sliding groove, and the rotary mechanism is inserted into the sliding groove and reciprocates in the sliding groove through the third telescopic mechanism so as to prevent the influence of the vibration mechanism on the rotary mechanism. The effect of improving the automatic smoothness and stability of the structure operation is achieved.

The beneficial effects of the invention are as follows: the compactness is improved; the production and preparation efficiency is improved; the moving stability of the structure is improved; the structure matching smoothness is improved; the automatic control and the quantification enable the production density to be more accurate; and the automatic smoothness and stability of the structure operation are improved.

Drawings

FIG. 1 is a perspective view of the present invention;

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

FIG. 3 is an enlarged view at A in FIG. 2;

fig. 4 is an enlarged view at B in fig. 2;

FIG. 5 is a schematic illustration of the connection of the buffer rack to the shaped housing;

FIG. 6 is a schematic diagram of a finished channel brick;

Fig. 7 is a second schematic diagram of the finished product of the runner brick.

In the figure: 1. the hydraulic machine comprises a main body, a lower shaping seat, an upper shaping seat, a lower shaping seat, a shaping shell, a shaping cavity, a 6 dosing mechanism, a 7-rotating mechanism, a 8-leveling mechanism, a 9-upper hydraulic machine, a 10-lower hydraulic machine, a 11-upper pressure rod, a 12-lower pressure rod, a 13-support rod, a 14-upper directional ring, a 15-lower directional ring, a 16-storage bin, a 17-feeding plate, a 18-support frame, a 19-telescopic mechanism, a 20-moving seat, a 21-dosing box, a 22-fixing rod, a 23-elastic mechanism, a 24-dosing ruler, a 25-dosing ruler, a 26-fixing block, a 27-telescopic mechanism, a 28-guiding plate, a 29-sealing cover, a 30-fixing ring, a 31-vibrating mechanism, a 32-mounting ring, a 33-buffering frame, a 34-clamping groove, a 35-pulley, a 36-connecting rod, a 37-moving rod, a 38-elastic mechanism, a 39-guiding sliding rail, a 40-moving groove, a 41-stabilizing seat, a 42-support plate, a 43-spacing ring, a 44-yielding hole, a 45-rotating disc, a 46-rotating disc, a 48-rotating mechanism, a 48-guiding plate, a material inlet and a 50-guiding plate.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. The following description of at least one exemplary embodiment is merely exemplary in nature and is in no way intended to limit the application, its application, or uses. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present application. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

The relative arrangement of the components, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present application unless it is specifically stated otherwise. Spatially relative terms, such as "upper," "lower," "left," "right," and the like, may be used in the embodiments for ease of description to describe one element or feature's relationship to another element or feature's illustrated in the figures. It will be understood that the spatial terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "under" other elements or features would then be oriented "on" the other elements or features. Thus, the exemplary term "lower" may encompass both an upper and lower orientation. The device may be otherwise fixed (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly. Meanwhile, it should be understood that the sizes of the respective parts shown in the drawings are not drawn in actual scale for convenience of description. Techniques, processes and equipment known to those of ordinary skill in the relevant art may not be discussed in detail, but should be considered part of the specification where appropriate. In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures.

In addition, the terms "first", "second", etc. are used to define the components, and are only for convenience of distinguishing the corresponding components, and the terms have no special meaning unless otherwise stated, and therefore should not be construed as limiting the scope of the present application.

Example 1:

As shown in fig. 1 and 2, the production equipment for the high-compactness soup way brick comprises a support 1, wherein the support 1 is movably connected with an upper shaping seat 2 and a lower shaping seat 3, the support 1 is connected with a shaping shell 4, the shaping shell 4 is arranged between the upper shaping seat 2 and the lower shaping seat 3, the lower shaping seat 3 is in scarf joint with one end of the shaping shell 4 to form a shaping cavity 5, the support 1 is connected with a quantitative feeding mechanism 6, a rotating mechanism 7 and a leveling mechanism 8, the shaping shell 4 and the lower shaping seat 3 are rotatably connected with the support 1 through the rotating mechanism 7, the quantitative feeding mechanism 6 is matched with the other end of the shaping shell 4, and the leveling mechanism 8 is connected with the shaping shell 4.

As shown in fig. 2, the support 1 is provided with an upper hydraulic press 9 and a lower hydraulic press 10, the upper hydraulic press 9 is connected with an upper compression bar 11, the lower hydraulic press 10 is connected with a lower compression bar 12, the upper compression bar 11 is connected with an upper shaping seat 2, the lower compression bar 12 is oppositely arranged with a lower shaping seat 3, the support 1 is provided with a support bar 13, one end of the support bar 13 is connected with the support 1, the other end of the support bar 13 is connected with an upper orientation ring 14 and a lower orientation ring 15, the upper compression bar 11 is spliced with the upper orientation ring 14, and the lower compression bar 12 is spliced with the lower orientation ring 15. The quantitative feeding mechanism 6 comprises a storage bin 16 and a feeding plate 17, the support 1 is connected with a support frame 18, the storage bin 16 is connected with the support frame 18, one end of the feeding plate 17 is arranged below the storage bin 16, the other end of the feeding plate 17 is arranged above the fixed cavity 5, the support 1 is connected with a telescopic mechanism I19, the feeding plate 17 is connected with a movable seat 20, the movable seat 20 is connected with the telescopic mechanism I19, and the feeding plate 17 is movably connected with the support 1 through the telescopic mechanism I19.

As shown in fig. 1,3 and 4, the support frame 18 is provided with a metering box 21, the metering box 21 is arranged between the storage bin 16 and the feeding plate 17, a fixed rod 22 is connected to the metering box 21, the support frame 18 is connected with a first elastic mechanism 23, the first elastic mechanism 23 is connected with the metering box 21, the first elastic mechanism 23 is sleeved with the fixed rod 22, the metering box 21 is connected with a first metering rod 24, the support frame 18 is connected with a second metering rod 25, and the first metering rod 24 is in sliding connection with the second metering rod 25.

As shown in fig. 3, the storage bin and the quantitative box 21 are connected with a fixed block 26, a second telescopic mechanism 27 and a material guiding plate 28, the fixed block 26 is connected with the second telescopic mechanism 27, the second telescopic mechanism 27 is connected with a sealing cover 29, the cover plate is movably connected through the second telescopic mechanism 27, and the material guiding plate 28 is arranged opposite to the sealing cover 29.

As shown in fig. 2, 4 and 5, the leveling mechanism 8 comprises a buffer frame 33 and a fixed ring 30, the support 1 is connected with a vibration mechanism 31, the vibration mechanism 31 is movably connected with the shaping shell 4, the fixed ring 30 is connected with the support 1, one end of the buffer frame 33 is slidably connected with the fixed ring 30, the shaping shell 4 is sleeved with a mounting ring 32, the mounting ring 32 is provided with a clamping groove 34, the other end of the buffer frame 33 is connected with the clamping groove 34, and the buffer frame 33 is elastically connected with the shaping shell 4. The buffer frame 33 comprises a pulley 35, a connecting rod 36, a movable rod 37 and a second elastic mechanism 38, wherein a guide sliding rail 39 is arranged on the fixed ring 30, the pulley 35 is in rolling connection with the guide sliding rail 39, one end of the connecting rod 36 is connected with the pulley 35, the other end of the connecting rod 36 is provided with a movable groove 40, one end of the movable rod 37 is inserted into the movable groove 40, the other end of the movable rod 37 is inserted into the clamping groove 34, the second elastic mechanism 38 is sleeved with the movable rod 37, one end of the second elastic mechanism 38 is connected with the connecting rod 36, and the other end of the second elastic mechanism 38 is connected with the mounting ring 32.

As shown in fig. 2, the support 1 is provided with a stabilizing seat 41, the stabilizing seat 41 comprises a support plate 42 and a limiting ring 43, the support plate 42 is connected with the support 1, the shaping shell 4 is slidably connected with the support plate 42, a yielding hole 44 is formed in the support plate 42, the aperture of the yielding hole 44 is larger than that of the pressing rod 12, the aperture of the yielding hole 44 is smaller than the outer diameter of the shaping shell 4, the limiting ring 43 is connected with the support plate 42, and the limiting ring 43 is sleeved with the shaping shell 4 and leaves a gap.

As shown in fig. 1 and 2, the rotating mechanism 7 comprises a rotating disc 45, a rotating ring 46 and a rotating mechanism 47, the rotating mechanism 47 is connected with the supporting plate 42, the rotating disc 45 is connected with the rotating mechanism 47, the rotating ring 46 is sleeved with the shaping shell 4, the rotating ring 46 is provided with a first tooth slot, the rotating disc 45 is provided with a second tooth slot matched with the first tooth slot, and the rotating ring 46 is meshed with the rotating disc 45.

As shown in fig. 2, the bracket 1 is connected with a third telescopic mechanism 48, the rotary mechanism 47 is connected with the third telescopic mechanism 48, the supporting plate 42 is provided with a sliding groove 49, and the rotary mechanism 47 is slidably connected with the sliding groove 49 through the third telescopic mechanism 48.

As shown in fig. 1-7: the lower bottoms of the storage bin 16 and the quantitative box 21 are respectively provided with a discharge hole 50, the quantitative box 21 is provided with a feed inlet 51, the feed inlet 50 of the quantitative box 21 and the discharge hole 51 of the storage bin are arranged in an up-down opposite mode, the discharge hole 50 of the quantitative box and the upper end of the feeding plate 17 are arranged in an opposite mode, and the sealing cover 29 is arranged at the discharge hole 51.

The guide plates 52 are connected in the cavities of the storage bin 16 and the quantitative box 21, and the guide plates 52 are connected with the discharge holes 51 to prevent the materials from being accumulated in the cavities of the storage bin 16 and the quantitative box 21, so that the discharging is smooth.

The height of the finished product runner brick (runner brick) is lower than the upper end surfaces of the lower shaping seat 3 and the shaping shell 4, so that the non-pressed filler is prevented from overflowing from the shaping cavity 5 after quantitative filling. The upper end surface of the shaping shell 4 is wedge-shaped, so that the upper shaping seat 2 enters the shaping cavity 5.

The feeding plate 17 is disposed below the quantitative box 21 and opposite to the discharge port 50, and the lower limit of the quantitative box 21 under gravity and the lower limit of the guide plate 28 are still higher than the highest point of the feeding plate 17 during quantitative operation, so as to prevent the structural collision from affecting the guide.

The support 1 is provided with two through holes, one through hole is provided with a telescopic mechanism III 48 so as to leave a movable gap for the telescopic mechanism III 48, the other through hole is used for installing the movable seat 20 and penetrating through the feeding plate 17, the support frame 18 is provided with a mounting hole, and the mounting hole is communicated with the through hole connected with the movable seat 20 so as to facilitate the installation of the telescopic mechanism I19, so that the structure is more compact.

When in use, the utility model is characterized in that: taking: the second telescopic mechanism 27 (adopting a cylinder structure) on the storage bin 16 is opened to enable the sealing cover 29 to move, and then the discharge hole 50 at the storage bin 16 is discharged into the feed inlet 51 of the quantitative box 21, the quantitative box 21 presses the first elastic mechanism 23 through adding gravity, and the discharging amount is observed through changing the relative positions of the first quantitative ruler 24 and the second quantitative ruler 25. After the required amount is reached, the discharge port 50 of the storage bin 16 is closed, so that the second telescopic mechanism 27 resets the sealing cover 29. The rotating mechanism 47 (adopting a rotating motor) is started, the rotating disc 45 rotates the rotating ring 46, the shaping shell 4 (the lower shaping seat 3) rotates on the stabilizing seat 41 along with the rotating ring 46, the telescopic mechanism II 38 on the quantitative box 21 is opened, the sealing cover 29 on the discharge hole 50 is opened, all materials in the quantitative box 21 enter the feeding plate 17, the lower end of the feeding plate 17 is arranged above one side of the shaping cavity 5, the annular filling is filled completely along with the rotation of the shaping cavity 5 until the materials in the quantitative box 21 are added completely, the sealing cover 29 on the quantitative box 21 is reset, and the telescopic mechanism I19 is started to enable the lower end of the feeding plate 17 to translate and leave the upper part of the shaping cavity 5. Stopping the rotating mechanism 47, starting the telescopic mechanism III 48 to enable the rotating mechanism 47 to drive the rotating disc 45 to move on the sliding groove 49, enabling the rotating disc 45 to leave the rotating ring 46, starting the vibrating mechanism 31 to enable the vibrating mechanism 31 to vibrate the shaping shell 4 (the lower shaping seat 3), and enabling materials to be evenly leveled in the shaping cavity 5 under vibration. Stopping vibrating after leveling, starting the upper hydraulic press 9 and the lower hydraulic press 10 to enable the upper compression rod 11 to drive the upper shaping seat 2 and the lower compression rod 12 to move towards the lower shaping seat 3 through the yielding holes 44, further enabling the upper shaping seat 2 and the lower shaping seat 3 to bidirectionally compress fillers to realize shaping and preparation of the runner bricks (as shown in fig. 6 and 7), and enabling the shaped upper shaping seat 2 to withdraw from the runner bricks by moving the lower shaping seat 3, and resetting the lower positioning seat 3 for next round of preparation.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. The utility model provides a production facility for high-compactness hot water way brick, characterized by, including support (1), support (1) remove and be connected with shaping seat (2) and lower shaping seat (3), support (1) are connected with shaping shell (4), shaping shell (4) are arranged in between shaping seat (2) and lower shaping seat (3), shaping cavity (5) are just formed to the one end scarf joint of shaping shell (4) down shaping seat (3), support (1) are connected with ration feeding mechanism (6), rotary mechanism (7) and leveling mechanism (8), shaping shell (4) and lower shaping seat (3) are connected through rotary mechanism (7) and support (1) rotation, the other end looks adaptation of ration feeding mechanism (6) and shaping shell (4), leveling mechanism (8) are connected with shaping shell (4).

2. The production equipment for the high-compactness soup bricks is characterized in that an upper hydraulic press (9) and a lower hydraulic press (10) are installed on the support (1), the upper hydraulic press (9) is connected with an upper pressing rod (11), the lower hydraulic press (10) is connected with a lower pressing rod (12), the upper pressing rod (11) is connected with an upper shaping seat (2), the lower pressing rod (12) is oppositely arranged with a lower shaping seat (3), a support rod (13) is arranged on the support (1), one end of the support rod (13) is connected with the support (1), an upper orientation ring (14) and a lower orientation ring (15) are connected with the other end of the support rod (13), the upper pressing rod (11) is connected with the upper orientation ring (14) in an inserting mode, and the lower pressing rod (12) is connected with the lower orientation ring (15) in an inserting mode.

3. The production equipment for high-compactness soup bricks is characterized in that the quantitative feeding mechanism (6) comprises a storage bin (16) and a feeding plate (17), the support (1) is connected with a supporting frame (18), the storage bin (16) is connected with the supporting frame (18), one end of the feeding plate (17) is arranged below the storage bin (16), the other end of the feeding plate (17) is arranged above the fixed cavity (5), the support (1) is connected with a telescopic mechanism I (19), the feeding plate (17) is connected with a movable seat (20), the movable seat (20) is connected with the telescopic mechanism I (19), and the feeding plate (17) is movably connected with the support (1) through the telescopic mechanism I (19).

4. A production facility for high-compactness soup way brick according to claim 3, characterized in that, support frame (18) is equipped with ration case (21), ration case (21) are arranged in between storage silo (16) and delivery sheet (17), be connected with dead lever (22) on ration case (21), support frame (18) are connected with elastic mechanism one (23), elastic mechanism one (23) is connected with ration case (21), elastic mechanism one (23) cup joints with dead lever (22), ration case (21) are connected with ration chi one (24), support frame (18) are connected with ration chi two (25), ration chi one (24) and ration chi two (25) sliding connection.

5. The production equipment for high-compactness soup bricks is characterized in that the storage bin (16) and the quantifying box (21) are connected with a fixed block (26), a telescopic mechanism II (27) and a material guiding plate (28), the fixed block (26) is connected with the telescopic mechanism II (27), the telescopic mechanism II (27) is connected with a sealing cover (29), the cover plate is movably connected through the telescopic mechanism II (27), and the material guiding plate (28) and the sealing cover (29) are oppositely arranged.

6. The production equipment for the high-compactness soup bricks is characterized in that the leveling mechanism (8) comprises a buffer frame (33) and a fixed ring (30), the support (1) is connected with a vibration mechanism (31), the vibration mechanism (31) is movably connected with the shaping shell (4), the fixed ring (30) is connected with the support (1), one end of the buffer frame (33) is slidably connected with the fixed ring (30), the shaping shell (4) is sleeved with a mounting ring (32), the mounting ring (32) is provided with a clamping groove (34), the other end of the buffer frame (33) is connected with the clamping groove (34), and the buffer frame (33) is elastically connected with the shaping shell (4).

7. The production equipment for the high-compactness soup bricks is characterized in that the buffer frame (33) comprises a pulley (35), a connecting rod (36), a movable rod (37) and a second elastic mechanism (38), a guide sliding rail (39) is arranged on the fixed ring (30), the pulley (35) is in rolling connection with the guide sliding rail (39), one end of the connecting rod (36) is connected with the pulley (35), the other end of the connecting rod (36) is provided with a movable groove (40), one end of the movable rod (37) is inserted into the movable groove (40), the other end of the movable rod (37) is inserted into the clamping groove (34), the second elastic mechanism (38) is sleeved into the movable rod (37), one end of the second elastic mechanism (38) is connected with the connecting rod (36), and the other end of the second elastic mechanism (38) is connected with the mounting ring (32).

8. The production equipment for the high-compactness soup bricks is characterized in that the support (1) is provided with a stabilizing seat (41), the stabilizing seat (41) comprises a support plate (42) and a limiting ring (43), the support plate (42) is connected with the support (1), the shaping shell (4) is slidably connected with the support plate (42), a yielding hole (44) is formed in the support plate (42), the aperture of the yielding hole (44) is larger than that of the pressing rod (12), the aperture of the yielding hole (44) is smaller than the outer diameter of the shaping shell (4), the limiting ring (43) is connected with the support plate (42), and the limiting ring (43) is sleeved with the shaping shell (4) and leaves a gap.

9. The production equipment for the high-compactness soup bricks according to claim 1 or 8, wherein the rotating mechanism (7) comprises a rotating disc (45), a rotating ring (46) and a rotating mechanism (47), the rotating mechanism (47) is connected with the supporting plate (42), the rotating disc (45) is connected with the rotating mechanism (47), the rotating ring (46) is sleeved with the shaping shell (4), the rotating ring (46) is provided with tooth grooves I, the rotating disc (45) is provided with tooth grooves II matched with the tooth grooves I, and the rotating ring (46) is connected with the rotating disc (45) in a meshed mode.

10. The production equipment for the high-compactness soup way bricks according to claim 9 is characterized in that the support (1) is connected with a telescopic mechanism III (48), the rotating mechanism (47) is connected with the telescopic mechanism III (48), the supporting plate (42) is provided with a sliding groove (49), and the rotating mechanism (47) is in sliding connection with the sliding groove (49) through the telescopic mechanism III (48).