CN215511904U

CN215511904U - Capsule shell blanking machine

Info

Publication number: CN215511904U
Application number: CN202121520819.2U
Authority: CN
Inventors: 阳伟
Original assignee: Chongqing Bi'an Industrial Co ltd
Current assignee: Chongqing Bi'an Industrial Co ltd
Priority date: 2021-07-05
Filing date: 2021-07-05
Publication date: 2022-01-14
Anticipated expiration: 2031-07-05

Abstract

The utility model relates to the technical field of medicine, in particular to a capsule shell blanking machine; the high-frequency vibration through the vibrator drives the vibrating arm to vibrate from side to side, thereby the mould board vibrates at high frequency, and then the capsule shell and the mould board relative motion in the shaping inslot make, work through flexible subassembly drives hydraulic telescoping rod and stretches out and draws back from top to bottom, make the gripper jaw stretch into the shaping inslot, thereby make the gripper jaw carry out the centre gripping to the capsule shell, further rotate through the steering column and drive the gripper jaw and rotate, make the capsule shell at shaping inslot rotation, thereby make capsule shell and shaping inslot separation, and then make the capsule shell drawing of patterns succeed.

Description

Capsule shell blanking machine

Technical Field

The utility model relates to the technical field of medicine, in particular to a capsule shell blanking machine.

Background

The capsule shell is an egg-shaped hollow shell which is made of edible medicinal gelatin through fine treatment and auxiliary materials and is used for containing solid powder and particles.

After the capsule shell is prepared, the capsule shell needs to be demoulded and then blanked.

The prior demoulding device has no processing component, and because the capsule shell has viscosity, the capsule shell is easy to stick on a mould, thereby causing demoulding failure.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a capsule shell blanking machine, and aims to solve the technical problem that a demoulding device in the prior art is not provided with a processing assembly, and because a capsule shell is sticky, the capsule shell is easy to stick on a mould, so that demoulding failure is caused.

In order to achieve the aim, the utility model provides a capsule shell blanking machine, which comprises a base, a supporting frame, a mould plate and a demoulding device, wherein the base is provided with a base seat;

the mould plate is connected with the supporting frame in a sliding mode and is positioned on one side, close to the base, of the supporting frame, and is provided with a forming groove which is positioned on one side, close to the supporting frame, of the mould plate;

the demolding device comprises a gripper jaw, a vibrating rod, a vibrator, a hydraulic telescopic rod, a steering rod, a sliding assembly, a telescopic assembly and a steering assembly, wherein the gripper jaw is connected with the support frame in a sliding manner, is connected with the mold plate in a rotating manner and is positioned on one side of the support frame close to the mold plate, the vibrating rod is fixedly connected with the mold plate and is positioned on one side of the mold plate close to the support frame, the vibrator is fixedly connected with the support frame and is positioned on one side of the support frame close to the vibrating rod, an output shaft of the vibrator is fixedly connected with the vibrating rod, the hydraulic telescopic rod is connected with the support frame in a sliding manner and is positioned on one side of the support frame close to the mold plate, the steering rod is fixedly connected with the hydraulic telescopic rod and is fixedly connected with the gripper jaw and is positioned on one side of the hydraulic telescopic rod close to the gripper jaw, the sliding assembly is fixedly connected with the supporting frame, the telescopic assembly is fixedly connected with the hydraulic telescopic rod, and the steering assembly is fixedly connected with the steering rod.

The capsule shell in the molding groove and the mold plate move relatively through the high-frequency vibration of the vibrator, and the clamping claws can clamp the capsule shell to rotate in the molding groove through the work of the telescopic assembly and the rotating assembly, so that the capsule shell is successfully demolded.

The sliding assembly comprises a guide sliding rail and a guide block, the guide sliding rail is fixedly connected with the support frame and is positioned on one side of the support frame close to the hydraulic telescopic rod; the guide block is connected with the guide sliding rail in a sliding mode, fixedly connected with the hydraulic telescopic rod and located on one side, close to the hydraulic telescopic rod, of the guide sliding rail.

The hydraulic telescopic rod is driven to move left and right by the guide block sliding left and right in the guide slide rail.

The telescopic assembly comprises a driving hydraulic cylinder and a connecting piston, the driving hydraulic cylinder is fixedly connected with the guide block and is positioned on one side of the guide block close to the hydraulic telescopic rod; the connecting piston is connected with the driving hydraulic cylinder in a sliding mode, is fixedly connected with the hydraulic telescopic rod and is located on one side, close to the hydraulic telescopic rod, of the driving hydraulic cylinder.

And the connecting piston slides up and down in the driving hydraulic cylinder through the reciprocating motion of the driving hydraulic cylinder, so that the hydraulic telescopic rod is driven to stretch up and down.

The driving hydraulic cylinder is provided with a sliding groove, and the sliding groove is located on one side, close to the connecting piston, of the driving hydraulic cylinder and is matched with the connecting piston.

Through the cooperation of the sliding grooves, the connecting piston is stable in the sliding of the driving hydraulic cylinder.

The steering assembly comprises a steering motor and a rotating bearing, the steering motor is fixedly connected with the hydraulic telescopic rod, is fixedly connected with the steering rod and is positioned on one side of the hydraulic telescopic rod close to the steering rod; the rotary bearing is fixedly connected with the steering motor, is rotatably connected with the steering rod and is positioned on one side of the steering motor, which is close to the steering rod.

Through the work of the steering motor, the steering rod can be driven to rotate.

The sliding assembly further comprises a rotary screw, the rotary screw is connected with the guide sliding rail in a rotating mode, is connected with the guide block in a rotating mode, and is located on one side, close to the guide block, of the guide sliding rail.

The rotary screw rod rotates forwards and backwards to drive the guide block to slide left and right in the guide slide rail.

The sliding assembly further comprises a rotating motor, the rotating motor is fixedly connected with the guide sliding rail and is positioned on one side, close to the rotating screw, of the guide sliding rail, and an output shaft of the rotating motor is fixedly connected with the rotating screw.

Through the work of the rotating motor, the rotating screw rod can be driven to rotate back and forth.

The die plate is also provided with a through hole, and the through hole is positioned on one side of the die plate close to the base and penetrates through the die plate.

Through the penetrating action of the through hole, redundant molding liquid can flow out through the through hole.

According to the capsule shell blanking machine, the vibrating rod is driven to vibrate left and right through the high-frequency vibration of the vibrator, so that the mould plate vibrates at a high frequency, the capsule shell in the forming groove and the mould plate move relatively, the hydraulic telescopic rod is driven to stretch up and down through the work of the telescopic assembly, the clamping claw extends into the forming groove, the clamping claw clamps the capsule shell, the clamping claw is further driven to rotate through the rotation of the steering rod, the capsule shell rotates in the forming groove, the capsule shell is separated from the forming groove, and the capsule shell is successfully demoulded.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a capsule shell blanking machine provided by the utility model.

Fig. 2 is a schematic structural view of the demolding device of the present invention.

Fig. 3 is a schematic view of a coupling structure of a vibration rod and a die plate according to the present invention.

Fig. 4 is a schematic view of the connection structure of the telescopic assembly and the driving hydraulic cylinder of the utility model.

Fig. 5 is a schematic view of the connection structure of the telescopic assembly and the hydraulic telescopic rod of the present invention.

Fig. 6 is a schematic view of a connection structure of the steering assembly and the steering rod of the present invention.

In the figure: 1-base, 2-support frame, 3-mould plate, 4-demoulding device, 31-forming groove, 32-through hole, 41-clamping jaw, 42-vibrating rod, 43-vibrator, 44-hydraulic telescopic rod, 45-steering rod, 46-sliding component, 47-telescopic component, 48-steering component, 100-capsule shell blanking machine, 461-guide sliding rail, 462-guide block, 463-rotary screw rod, 464-rotary motor, 471-connecting piston, 472-driving hydraulic cylinder, 4721-sliding chute, 481-steering motor and 482-rotary bearing.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1 to 6, the present invention provides a capsule shell blanking machine 100, which includes a base 1, a supporting frame 2, a mold plate 3 and a demolding device 4;

the supporting frame 2 is fixedly connected with the base 1 and is positioned on one side of the base 1, the mould plate 3 is connected with the supporting frame 2 in a sliding manner and is positioned on one side of the supporting frame 2 close to the base 1, the mould plate 3 is provided with a forming groove 31, and the forming groove 31 is positioned on one side of the mould plate 3 close to the supporting frame 2;

demoulding device 4 includes gripper jaw 41, vibrating arm 42, vibrator 43, hydraulic telescoping rod 44, steering column 45, sliding assembly 46, flexible subassembly 47 and turns to subassembly 48, gripper jaw 41 with support frame 2 sliding connection, and with mould board 3 rotates to be connected, and is located support frame 2 is close to one side of mould board 3, vibrating arm 42 with mould board 3 fixed connection, and is located mould board 3 is close to one side of support frame 2, vibrator 43 with support frame 2 fixed connection, and is located support frame 2 is close to one side of vibrating arm 42, the output shaft of vibrator 43 with vibrating arm 42 fixed connection, hydraulic telescoping rod 44 with support frame 2 sliding connection, and is located support frame 2 is close to one side of mould board 3, steering column 45 with hydraulic telescoping rod 44 fixed connection, and is fixedly connected with the clamping jaw 41, and is located on one side of the hydraulic telescopic rod 44 close to the clamping jaw 41, the sliding component 46 is fixedly connected with the support frame 2, the telescopic component 47 is fixedly connected with the hydraulic telescopic rod 44, and the steering component 48 is fixedly connected with the steering rod 45.

In this embodiment, the base 1 is made of stainless steel, the supporting frame 2 is made of door-shaped stainless steel, the supporting frame 2 is welded and fixed with the base 1 and is located above the base 1, the mold plate 3 is slidably connected with the supporting frame 2 through the vibrating rod 42 and is located inside the supporting frame 2, the mold plate 3 has a plurality of forming grooves 31, the forming grooves 31 are located above the mold plate 3, the forming grooves 31 are used for preparing capsule shells, the clamping claws 41 are clampable claws, the clamping claws 41 are slidably connected with the supporting frame 2 through the sliding assemblies 46 and are rotatably connected with the mold plate 3 through the rotating assemblies, so that the clamping claws 41 can slide in the supporting frame 2 and can rotate relative to the mold plate 3, the vibrating rod 42 is made of stainless steel, the utility model discloses a mould, including mould board 3, vibrating bar 42, support frame 2, steering column 45, vibrating bar 43, hydraulic telescopic rod 44, hydraulic telescopic rod 41, clamping jaw 41, vibrator 43, support frame 2, support frame 44, the vibrating bar 42 is fixed on the outside of support frame 2, the vibrating bar 42 is fixed on the outside of support frame 3, the model of vibrator 43 is the miniature vibrating motor of power ox, vibrator 43 with support frame 2 passes through bolt fixed connection, and install in the outside of support frame 2, the output shaft of vibrator 43 with vibrating bar 42 passes through bolt fixed connection, hydraulic telescopic rod 44 is the stainless steel telescopic link, hydraulic telescopic rod 44 with support frame 2 passes through sliding assembly 46 sliding connection, and is located the below of support frame 2, steering column 45 is stainless steel material, steering column 45 with hydraulic telescopic rod 44 fixed connection, and with clamping jaw 41 passes through bolt fixed connection, and is located hydraulic telescopic rod 44 with between clamping jaw 41, so, through the high-frequency vibration drive of vibrator 43 the vibrating bar 42 horizontal vibration, therefore, the mold plate 3 vibrates at high frequency, so that the capsule shell in the molding groove 31 and the mold plate 3 move relatively, the telescopic hydraulic rod 44 is driven to extend and retract up and down through the operation of the telescopic assembly 47, the clamping claw 41 extends into the molding groove 31, so that the clamping claw 41 clamps the capsule shell, the rotation of the steering rod 45 further drives the clamping claw 41 to rotate, the capsule shell rotates in the molding groove 31, the capsule shell is separated from the molding groove 31, and the capsule shell is successfully demolded.

Further, referring to fig. 2 and fig. 4, the sliding assembly 46 includes a guiding rail 461 and a guiding block 462, the guiding rail 461 is fixedly connected to the supporting frame 2 and is located at a side of the supporting frame 2 close to the hydraulic telescopic rod 44; the guide block 462 is slidably connected to the guide rail 461, and is fixedly connected to the hydraulic telescopic rod 44, and is located on one side of the guide rail 461, which is close to the hydraulic telescopic rod 44.

Further, referring to fig. 2 and 4, the sliding assembly 46 further includes a rotating screw 463 and a rotating motor 464, wherein the rotating screw 463 is rotatably connected to the guiding slide 461 and rotatably connected to the guiding block 462, and is located at a side of the guiding slide 461 close to the guiding block 462; the rotating motor 464 is fixedly connected to the guide rail 461 and is located on one side of the guide rail 461 close to the rotating screw 463, and an output shaft of the rotating motor 464 is fixedly connected to the rotating screw 463.

In this embodiment, the guide rail 461 is a rectangular rail having a downward sliding slot, the guide rail 461 is fixedly connected to the support frame 2 by a bolt and is located below the support frame 2, the guide block 462 is a rectangular block having a threaded hole, the width of the guide block 462 is the same as the width of the sliding slot of the guide rail 461, the guide block 462 is slidably connected to the guide rail 461 by an internal roller and is fixedly connected to the hydraulic telescopic rod 44 and is located in the guide rail 461, the rotary screw 463 is a stainless steel bolt having a thread on an outer surface, the rotary screw 463 is rotatably connected to the guide rail 461 by a bearing and passes through the guide block 462 and is located in the guide rail 461, the rotary motor 464 is a dc motor, the rotary motor 464 is fixedly connected to the guide rail 461 by a bolt, and is located on the left side of the guide slide rail 461, and the output shaft of the rotating motor 464 is fixedly connected with the rotating screw 463 through a bolt, so that the rotating screw 463 is driven to rotate back and forth through the operation of the rotating motor 464, and the guide block 462 is driven to slide left and right in the guide slide rail 461, and further the hydraulic telescopic rod 44 is driven to move left and right.

Further, referring to fig. 5, the telescopic assembly 47 includes a driving hydraulic cylinder 472 and a connecting piston 471, the driving hydraulic cylinder 472 is fixedly connected to the guide block 462 and is located at a side of the guide block 462 close to the hydraulic telescopic rod 44; the connecting piston 471 is slidably connected with the driving hydraulic cylinder 472, is fixedly connected with the hydraulic telescopic rod 44, and is located at one side of the driving hydraulic cylinder 472 close to the hydraulic telescopic rod 44; the driving hydraulic cylinder 472 has a sliding groove 4721, and the sliding groove 4721 is located on one side of the driving hydraulic cylinder 472 close to the connecting piston 471 and is engaged with the connecting piston 471.

In this embodiment, the driving hydraulic cylinder 472 is a piston type hydraulic cylinder, the driving hydraulic cylinder 472 is fixedly connected to the guide block 462 through a bolt and is located below the guide block 462, the connecting piston 471 is a cast iron piston, the connecting piston 471 is slidably connected to the driving hydraulic cylinder 472 through the sliding groove 4721, is fixedly connected to the hydraulic telescopic rod 44 in a welding manner, and is located inside the driving hydraulic cylinder 472, so that the connecting piston 471 slides up and down in the driving hydraulic cylinder 472 through the reciprocating motion of the driving hydraulic cylinder 472, thereby driving the hydraulic telescopic rod 44 to extend and retract up and down.

Further, referring to fig. 5 and 6, the steering assembly 48 includes a steering motor 481 and a rotary bearing 482, wherein the steering motor 481 is fixedly connected with the hydraulic telescopic rod 44, fixedly connected with the steering rod 45, and located on one side of the hydraulic telescopic rod 44 close to the steering rod 45; the rotary bearing 482 is fixedly connected to the steering motor 481, is rotatably connected to the steering rod 45, and is located on a side of the steering motor 481 close to the steering rod 45.

In this embodiment, the steering motor 481 is a dc motor, the steering motor 481 is fixedly connected to the bottom of the hydraulic telescopic rod 44 by a bolt, is fixedly connected to the steering rod 45 by a bolt, and is located below the hydraulic telescopic rod 44, the rotary bearing 482 is a cylindrical roller bearing, and the rotary bearing 482 is fixedly connected to the steering motor 481 by a bolt, is rotatably connected to the steering rod 45 by an outer surface, and is located between the steering motor 481 and the steering rod 45, so that the steering rod 45 can be rotated by the operation of the steering motor 481.

Further, referring to fig. 3, the mold plate 3 further has a through hole 32, and the through hole 32 is located at a side of the mold plate 3 close to the base 1 and penetrates through the mold plate 3.

In the present embodiment, the number of the through holes 32 is four, and the through holes 32 are located at four corners of the mold plate 3 and penetrate through the mold plate 3, so that the excess molding liquid can flow out through the through holes 32 by the penetrating action of the through holes 32.

According to the capsule shell blanking machine 100, the vibrating rod 42 is driven by the high-frequency vibration of the vibrator 43 to vibrate left and right, so that the die plate 3 vibrates in a high-frequency manner, the capsule shell in the forming groove 31 and the die plate 3 move relatively, the hydraulic telescopic rod 44 is driven by the operation of the telescopic assembly 47 to stretch up and down, the clamping claw 41 extends into the forming groove 31, the clamping claw 41 clamps the capsule shell, the clamping claw 41 is further driven to rotate by the rotation of the steering rod 45, the capsule shell rotates in the forming groove 31, the capsule shell is separated from the forming groove 31, and the capsule shell is successfully demoulded.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims

1. A capsule shell blanking machine is characterized by comprising a base, a supporting frame, a mould plate and a demoulding device;

2. The capsule shell blanking machine of claim 1,

3. The capsule shell blanking machine of claim 2,

4. The capsule shell blanking machine of claim 3,

the driving hydraulic cylinder is provided with a sliding groove, and the sliding groove is positioned on one side, close to the connecting piston, of the driving hydraulic cylinder and is matched with the connecting piston.

5. The capsule shell blanking machine of claim 1,

6. The capsule shell blanking machine of claim 2,

7. The capsule shell blanking machine of claim 6,

8. The capsule shell blanking machine of claim 1,