CN214493390U - Filling and densifying platform - Google Patents

Abstract

The utility model provides a filling densification platform, include: the device comprises a rack, wherein a placing plate is arranged on the rack, a placing hole for placing a cup body is formed in the placing plate, filling heads arranged corresponding to the placing hole are suspended above the placing plate, and a thickening cup supporting assembly arranged corresponding to the placing hole is arranged below the placing plate; the tail end of the filling head is covered with a pressing head, the pressing head is provided with a through hole for powder to be extruded, the densification cup supporting assembly is configured to support the cup body to rise to a first preset height so that the filling head can fill powder into the cup body or support the cup body to rise to a second preset height so that the pressing head can compact the powder in the cup body, and the first preset height is lower than the second preset height. The utility model provides a filling platform among the prior art need set up filling mechanism and densification mechanism alone and lead to the problem that the complete machine structure is complicated, bulky.

Description

Filling and densifying platform

Technical Field

The utility model relates to a filling field of densifying, more specifically relates to a filling platform of densifying.

Background

With the continuous pursuit of people on the taste of the beverage and the emphasis on the convenience of carrying, storing, extracting and the like of the beverage, the beverage is processed into the beverage capsule which is convenient to store and carry. The capsule coffee is a capsule beverage, and is prepared by grinding coffee beans into coffee powder and then filling the coffee powder into an aluminum capsule, so that the problems of acid change, oxidation and the like of common coffee beans or coffee powder after contacting air are solved.

The existing capsule coffee is easy to cause the phenomenon of material cup accumulation in the production and filling processes, and the filling effect is poor due to gaps among particles of powder. For solving this technical problem, current scheme generally can set up two stations simultaneously and carry out filling and densification respectively to the material cup, but, owing to set up two stations simultaneously and carry out filling and densification to the material cup, can lead to the overall structure complicacy and the bulky of current filling mechanism.

In view of the above, there is a need for an improved filling mechanism in the prior art to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to disclose a filling densification platform to the filling platform of solving among the prior art needs to set up filling mechanism and densification mechanism alone and leads to the problem that the complete machine structure is complicated, bulky.

In order to achieve the above object, the utility model provides a filling densification platform, include:

the device comprises a rack, wherein a placing plate is arranged on the rack, a placing hole for placing a cup body is formed in the placing plate, a filling head arranged corresponding to the placing hole is suspended above the placing plate, and a thickening cup supporting assembly arranged corresponding to the placing hole is arranged below the placing plate;

the tail end of the filling head is covered with a pressing head, a through hole for powder extrusion is formed in the pressing head, the densification cup supporting assembly is configured to support the cup body to rise to a first preset height so that the filling head can fill powder into the cup body or support the cup body to rise to a second preset height so that the pressing head can compact the powder in the cup body, and the first preset height is lower than the second preset height.

As a further improvement, the densification support cup assembly comprises a cup holder for receiving the cup body, a pressure sensor connected with the cup holder, a driver for controlling the up-and-down motion of the cup holder, wherein the pressure sensor is used for detecting the pressing pressure of the pressing head to the powder in the cup body.

As a further improvement of the utility model, the densification support cup assembly further comprises a stroke sensor for detecting the movement distance of the support cup.

As a further improvement of the present invention, the driver is formed in a densified power box, and a stroke plate connected to the driver for controlled longitudinal movement is disposed above the densified power box, and the cup holder is disposed on the stroke plate.

As a further improvement of the present invention, one side of the stroke plate is formed with an edge the detection plate extending in the length direction of the stroke plate, the stroke sensor is arranged in the outside of the densification power box and in the longitudinal direction the position of the detection plate is opposite.

As a further improvement of the present invention, the driver is configured as a crank link mechanism or a lift cylinder.

As a further improvement, the filling head comprises a conical tube, and a straight tube connected to the end of the conical tube, the filling head is internally provided with a self-extending conical tube to the end screw rod, and the pressing head covers the end surface of the straight tube and the end surface of the screw rod.

As a further improvement of the utility model, the upper end of the conical pipe is connected with a measuring conical hopper, and the contraction part of the measuring conical hopper is connected with the flaring part of the conical pipe;

a cylindrical shell is arranged above the metering cone hopper, a transmission rod is contained in the cylindrical shell, the top end of the transmission rod is connected with a driving assembly, and the tail end of the transmission rod is connected with the top end of the screw rod.

As a further improvement, the top cover of cylinder casing has the apron, be formed with the feed inlet on the apron, install on the apron and be used for the holding drive assembly's headstock.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses a filling densification platform holds in the palm the cup through the densification and rises to first preset height to through the densification, and with the filling head through corresponding the position to cup filling powder, and hold in the palm the cup through the densification and rise to the second and preset the height, carry out the compaction to the powder in the cup with the terminal press head of filling head through corresponding the position, thereby accomplish through same densification support cup subassembly and carry out the filling powder and carry out the purpose that the densification to the filling powder to the cup. Therefore, the utility model discloses a filling densification platform not only can carry out filling and compaction to the powder, thereby owing to accomplish through same densification support cup subassembly and carry out filling powder and compaction powder to the cup and can greatly simplify the structure of filling densification platform moreover. The problem of filling platform among the prior art need set up filling mechanism and densification mechanism alone and lead to complete machine structure complicacy, bulky is solved.

Drawings

Fig. 1 is a schematic perspective view of a filling and densifying platform according to an embodiment of the present invention;

fig. 2 is a schematic front view of a filling and densifying platform according to an embodiment of the present invention;

fig. 3 is a schematic connection structure diagram between the filling head, the metering cone and the cylindrical shell according to an embodiment of the present invention;

figure 4 is a schematic cross-sectional view of a filling head of an embodiment of the present invention;

fig. 5 is a schematic connection structure diagram of a driving assembly, a cylindrical shell and a measuring cone bucket according to an embodiment of the invention;

fig. 6 is a schematic block diagram of a densification cup assembly in accordance with an embodiment of the present invention.

Detailed Description

The present invention is described in detail with reference to the embodiments shown in the drawings, but it should be understood that these embodiments are not intended to limit the present invention, and those skilled in the art should understand that the functions, methods, or structural equivalents or substitutions made by these embodiments are within the scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", "positive", "negative", 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 simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Please refer to fig. 1 to 6, which illustrate a specific embodiment of the filling and densifying platform of the present invention.

As described with reference to fig. 1 to 6, the filling and densifying platform of the present embodiment includes: the lead screw device comprises a machine frame 10, wherein a lead screw seat 101 used for installing a lead screw 102 is arranged on the machine frame 10, and an air cylinder 103 (or a motor) used for controlling the lead screw to move along the z direction is arranged on one side of the machine frame 10. The frame 10 is configured as two mounting plates arranged longitudinally (i.e., in the y-axis direction in fig. 1) and symmetrically, each of the mounting plates being formed with a mounting hole 104 through which the screw base 101 penetrates in the z-axis direction and supports the screw base 101. A shelf 20 is disposed on the housing 10. Further, the resting plate 20 is placed on the screw rod 102 (i.e. the resting plate 20 is arranged on the screw rod 102 in the x-axis direction), and the resting plate 20 is driven to move along the length direction of the screw rod seat 101 when the screw rod 102 is controlled by the air cylinder 103 (or the motor) to move. Wherein the longitudinal depth of the mounting hole 104 is higher than the height from the bottom of the screw base 101 to the upper surface of the resting plate 20. The shelving plate 20 is provided with a placing hole 201 for placing the cup body, a filling head 30 arranged corresponding to the placing hole 201 is suspended above the shelving plate 20, the tail end of the filling head 30 is covered with a pressing head 301, and the pressing head 301 is provided with a through hole for extruding the powder.

Specifically, the filling head 30 is constituted by a tapered tube 302 and a straight tube 303 connected to the end of the tapered tube 302. The upper end of the conical tube 302 is connected with a metering cone 304, and the contraction part of the metering cone 304 is connected with the flaring part of the conical tube 302. Above the metering cone 304, a cylindrical housing 305 is arranged, in which cylindrical housing 305 a transmission rod 306 is accommodated which extends to the metering cone 304. A screw 307 is arranged in the filling head 30 extending from the conical tube 302 to the end of the straight tube, and the end of the drive rod 306 is connected to the tip of the screw 307. The pressing head 301 covers the distal end surface of the straight tube 303 and is attached to the distal end surface of the screw 307. A cover plate 308 covers the cylindrical housing 305, and a feed inlet 3081 for feeding the powder into the cylindrical housing 305 through the metering cone 304 into the filling head 30 is formed in the cover plate 308. The cover plate 308 is provided with a power box 309, the power box 309 is internally provided with a driving component which sequentially penetrates through the bottom plate of the power box and the cover plate 308, and the driving component is connected with the top end of the transmission rod 306. Of these, only the bottom plate of the power box 309 is shown in fig. 1 or 2.

Therefore, the driving assembly in the power box 309 controls the transmission rod 306 to drive the screw 307 to rotate at a high speed in the filling head 30, so that the powder is extruded through a gap between the screw 307 and the inner wall of the straight pipe 303, and the powder extruded by the filling head 30 is filled into the cup body, so that the powder is filled.

In this embodiment, a densification supporting cup assembly is disposed below the placing plate 20, where the placing hole 201 is correspondingly disposed, and the densification supporting cup assembly is configured to support the cup body to rise to a first preset height for the filling head 30 to fill the cup body with powder or to rise to a second preset height for the pressing head 301 to compact the powder in the cup body. The first predetermined height is lower than the second predetermined height. It should be noted that, the specific implementation process of the densification cup supporting assembly according to the embodiment that the cup body is lifted to the first preset distance and the cup body is lifted to the second preset distance is well known in the art, and detailed description thereof is omitted.

It should be understood that, when filling head 30 filled the powder in to the cup, the densification support cup subassembly holds up the cup and rises to first preset height, makes the rim of a cup be close to filling head 30 end to make the powder fill to the cup reliably when filling head 30 extruded the powder, reduce because the error of the relative position between filling head 30 and the rim of a cup leads to the powder to spill at the rim of a cup and the rim of a cup outside and cause the filling environment variation. Stop at filling head 30 to the cup filling and need press the real-time to the powder in the filling back cup, the densification holds in the palm the cup subassembly and holds up the cup and rise to the second and predetermine the height, and this second is predetermine highly to be greater than first height of predetermineeing, make filling head 30 terminal press head 301 stretch into to the cup in the powder surface, with through press head 301 flattening reliably and press the cup in the powder, improve the interior powder surface's of cup roughness and increase the density of the interior powder of cup, thereby improve the filling effect of filling head 30 to the interior powder of cup.

Therefore, the filling and densifying platform of the embodiment supports the cup body to rise to the first preset height through the densifying support cup assembly, so that powder is filled in the cup body through the filling head 30 at the corresponding position, the cup body is supported by the densifying support cup assembly to rise to the second preset height, the powder in the cup body is compacted through the pressing head 301 at the tail end of the filling head at the corresponding position, and the purposes of filling the powder in the cup body and densifying the filling powder are achieved through the same densifying support cup assembly. Therefore, the filling and densifying platform of the embodiment can not only fill and compact the powder, but also greatly simplify the structure of the filling and densifying platform due to the fact that the powder and the compacted powder are filled in the cup body through the same densifying support cup assembly. Therefore, the problems that the filling platform in the prior art needs to be provided with the filling mechanism and the densifying mechanism independently, so that the whole machine is complex in structure and large in size are solved.

In the above embodiment, the densified cup holder assembly includes a cup holder 401 for receiving a cup body, a pressure sensor 402 connected to the cup holder 401, and a driver 403 for controlling the up-and-down movement of the cup holder 401, and the driver 403 may be configured as a driving mechanism such as a crank link mechanism or a lifting cylinder. The pressure sensor 402 is used to apply a pressing force F to the powder in the cup by the pressing head. The densification cup assembly further includes a stroke sensor 404 for detecting a movement distance of the cup 401. Specifically, the driver 403 is formed in a densified power box 40, and a stroke plate 405 connected to the driver 403 for controlled longitudinal movement is disposed above the densified power box 40, and the cup holder 401 is disposed on the stroke plate 405. One side of the stroke plate 405 is formed with a detection plate 406 extending in the length direction of the stroke plate 405 and protruding from the outer side of the densification power box 40, and the stroke sensor 404 is disposed at the outer side of the densification power box 40 opposite to the position of the detection plate 406 in the longitudinal direction so that the moving distance measured for the detection plate 406 by the stroke sensor 404 is determined as the moving distance S of the tray cup 401.

It should be understood that the "powder" referred to in this embodiment may be configured as edible powder such as coffee powder, milk powder, flour, etc., or may be configured as chemical powder. However, when different powders are filled, the pressing pressure F of the filling head 30 against the powders is different, and the movement distance S of the carrier cup 401 for lifting the cup is also different. In order to improve the filling effect of the target powder, the filling and densifying platform of the embodiment detects the pressing pressure F of the pressing head 401 on the powder through the pressure sensor 402, and measures the movement distance S of the cup holder 401 in combination with the stroke sensor 404 to determine the movement distance S between the pressing pressure F and the cup holder 401, which are matched with the target powder, and fills the target powder according to the determined movement distance S between the pressing pressure F and the cup holder 401, so as to improve the filling quality and the filling effect of the powder.

The above list of details is only for the practical implementation of the present invention, and they are not intended to limit the scope of the present invention, and all equivalent implementations or modifications that do not depart from the technical spirit of the present invention should be included in the scope of the present invention.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (9)

1. A filling densification platform, comprising:

the device comprises a rack, wherein a placing plate is arranged on the rack, a placing hole for placing a cup body is formed in the placing plate, a filling head arranged corresponding to the placing hole is suspended above the placing plate, and a thickening cup supporting assembly arranged corresponding to the placing hole is arranged below the placing plate;

the tail end of the filling head is covered with a pressing head, a through hole for powder extrusion is formed in the pressing head, the densification cup supporting assembly is configured to support the cup body to rise to a first preset height so that the filling head can fill powder into the cup body or support the cup body to rise to a second preset height so that the pressing head can compact the powder in the cup body, and the first preset height is lower than the second preset height.

2. The filling densification platform of claim 1, wherein,

the densification support cup assembly comprises a cup support for supporting the cup body, a pressure sensor connected with the cup support and a driver for controlling the cup support to move up and down, wherein the pressure sensor is used for detecting the pressing pressure of the pressing head on powder in the cup body.

3. The filling densification platform of claim 2, wherein,

the densification saucer cup assembly further comprises a stroke sensor for detecting a movement distance of the saucer cup.

4. The filling densification platform of claim 3, wherein,

the driver is formed in a densified power box, a stroke plate which is connected with the driver and is controlled to move longitudinally is arranged above the densified power box, and the cup holder is arranged on the stroke plate.

5. The filling densification platform of claim 4, wherein,

and a detection plate extending along the length direction of the stroke plate is formed on one side of the stroke plate, and the stroke sensor is arranged on the outer side of the densification power box and is opposite to the position of the detection plate in the longitudinal direction.

6. The filling densification platform of claim 4, wherein,

the driver is configured as a crank-link mechanism or a lift cylinder.

7. The filling densification platform of any of claims 1-6,

the filling head comprises conical tube, with the terminal continuous straight tube of conical tube, arrange certainly in the filling head the conical tube extends to the terminal screw rod of straight tube, just the pressure head cover in the terminal surface of straight tube and with the terminal surface laminating of screw rod.

8. The filling densification platform of claim 7, wherein,

the upper end of the conical pipe is connected with a metering conical hopper, and the contraction part of the metering conical hopper is connected with the flaring part of the conical pipe;

a cylindrical shell is arranged above the metering cone hopper, a transmission rod is contained in the cylindrical shell, the top end of the transmission rod is connected with a driving assembly, and the tail end of the transmission rod is connected with the top end of the screw rod.

9. The filling densification platform of claim 8,

the cylinder casing's top covers there is the apron, be formed with the feed inlet on the apron, install on the apron and be used for the holding drive assembly's headstock.

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