CN223943757U - Energy stick former - Google Patents

Abstract

The utility model relates to the technical field of energy rod production, in particular to energy rod forming equipment which comprises an operation table, a stamping assembly, a sliding cover, a reciprocating driving assembly, a transmission assembly, a weighing device and a linear driving assembly, wherein a groove is formed in the operation table, a group of conveying assemblies are respectively arranged at two ends of the operation table, a die holder is arranged on the operation table, the stamping assembly is arranged at the bottom of the operation table and is matched with the die holder, the sliding cover is arranged in the groove in a sliding manner, a through hole and a discharging hopper matched with the through hole are formed in the sliding cover, a flexible scraping plate is arranged in the discharging hopper, the reciprocating driving assembly is in driving connection with the flexible scraping plate, the transmission assembly is in driving connection with the reciprocating driving assembly and the conveying assemblies, the weighing device is arranged on the sliding cover, the weighing device is connected with a storage barrel, a discharging pipe is arranged at the bottom of the storage barrel and is inserted into the discharging hopper, and the linear driving assembly is in driving connection with the sliding cover. The utility model can rapidly complete quantitative feeding, uniformly disperse raw materials into each die cavity, and does not need to consume extra electric energy.

Description

Energy stick former

Technical Field

The utility model relates to the technical field of energy rod production, in particular to energy rod forming equipment.

Background

The energy stick, as the name implies, is a bar-like food for supplementing energy, also called an energy sports nutritional food, which mainly consists of carbohydrate and protein. The existing lactobacillus fermentation energy bar is prepared by adding lactobacillus into raw materials, so that the energy bar is prepared after fermentation, and the energy bar not only maintains the high energy of the traditional energy bar, but also enriches the flavor of the energy bar. In the existing production equipment and living environment, gas radiation, electronic product radiation, ionizing radiation and the like are harmful to human health, in order to enable the compressed biscuits to have a radiation-resistant function, spirulina and kelp powder are added into energy rod raw materials during energy rod production, and the energy rod with radiation resistance is prepared after fermentation, and is formed by stamping through a die during forming, however, the traditional stamping forming equipment is low in working efficiency.

The chinese patent with the publication number CN220897790U discloses a compression device for making compressed biscuits, which comprises a forming die, a feeding assembly and a conveying assembly, wherein the feeding assembly can continuously provide raw materials for the forming die through reciprocating movement, a pressing plate arranged on a hopper can provide blocking pressure for a compression block, the biscuits are ensured to be compressed and formed, and the arranged hopper can push the compressed biscuits onto the conveying assembly in the process of return stroke, so that the blanking is convenient.

However, the device still has the defect that as the die is provided with a plurality of holes, the raw materials in each hole cannot be uniformly dispersed during blanking, so that the biscuits and the like formed in each die cavity have obvious differences.

Disclosure of utility model

The utility model aims to solve the problems in the background art and provides energy rod forming equipment.

The technical scheme of the utility model is that the energy rod forming equipment comprises an operation table, wherein a groove is formed in the operation table, two ends of the operation table are respectively provided with a chute, a conveying assembly is arranged in the chute, and a die holder with the upper end face being flush with the bottom surface of the groove is arranged on the operation table;

The stamping component is arranged at the bottom of the operating platform and is matched with the die holder;

The sliding cover is arranged in the groove in a sliding way, a through hole matched with the die holder is formed in the sliding cover, a discharge hopper matched with the through hole is formed in the sliding cover, a movable plate is arranged in the discharge hopper in a sliding way, a flexible scraping plate is arranged at the bottom of the movable plate, and the bottom surface of the flexible scraping plate is in contact with the bottom surface of the groove;

the reciprocating driving assembly is arranged on the discharge hopper and is in driving connection with the movable plate;

The transmission assembly is in transmission connection with the reciprocating driving assembly and the conveying assembly;

The weighing device is arranged on the sliding cover, the weighing device is connected with the storage vat, the bottom of the storage vat is provided with a discharging pipe, the discharging pipe is inserted into the discharging hopper, and the discharging pipe is provided with a valve;

And the linear driving assembly is arranged on the operating platform and is in driving connection with the sliding cover.

Preferably, the conveying assembly comprises two transmission shafts, a conveying belt and a first motor, wherein the two transmission shafts are rotationally connected with the operation table, two transmission rollers are symmetrically arranged on the transmission shafts, the transmission rollers on the two sides are respectively positioned in the inclined grooves on the corresponding sides, the two transmission rollers on the same side are respectively in transmission connection through a group of conveying belts, the body of the first motor is connected with the operation table, and the output end of the first motor is connected with one transmission shaft.

Preferably, the reciprocating driving assembly comprises a reciprocating screw rod, the reciprocating screw rod is rotationally connected with the discharging hopper, and a shuttle of the reciprocating screw rod is connected with the movable plate.

The transmission assembly comprises a first belt wheel, a second belt wheel, a toothed belt, a worm wheel and a worm, wherein a spline is arranged on a transmission shaft, a fixing frame is arranged on a discharge hopper and is in sliding connection with an operating platform, the end part of a reciprocating screw rod is rotationally connected with the fixing frame, a rotating shaft is rotationally arranged on the fixing frame, the first belt wheel is coaxially connected with the reciprocating screw rod, the second belt wheel is coaxially connected with the worm wheel, the second belt wheel is in transmission connection with the first belt wheel through the toothed belt, the worm is coaxially and slidingly arranged on the transmission shaft and the spline, and the worm is meshed with the worm wheel.

Preferably, the stamping assembly comprises a telescopic rod, a stamping head, a hydraulic cylinder and a controller, wherein a plurality of die cavities are arranged on a die holder, a supporting frame is arranged at the bottom of an operating platform, a body of the telescopic rod is connected with the supporting frame, the movable end of the telescopic rod is connected with a gravity sensor, the detection end of the gravity sensor is connected with a mounting plate, the stamping head is connected with the mounting plate and corresponds to the die cavities one by one, the body of the hydraulic cylinder is connected with the supporting frame, the output end of the hydraulic cylinder is connected with the body of the gravity sensor, the controller is arranged on the operating platform, and the controller is electrically connected with the gravity sensor and is in control connection with the hydraulic cylinder.

Preferably, the weighing device and the valve are electrically connected with the controller.

Preferably, the stirring assembly and the feed hopper communicated with the interior of the stirring assembly are arranged in the storage barrel, the stirring assembly comprises a second motor and a stirring paddle, a stirring shaft is arranged on a barrel cover of the storage barrel, a body of the second motor is connected with the barrel cover, an output end of the second motor is connected with the stirring shaft, and the stirring paddle is arranged on the stirring shaft.

Compared with the prior art, the utility model has the following beneficial technical effects:

The two ends of the operation table are respectively provided with the chute, the conveying assembly is arranged in the chute, the operation table is provided with the die holder and the punching assembly which moves upwards from the bottom and is matched with the die holder in a centering manner, the operation table is provided with the sliding cover, and the sliding cover is provided with the discharging hopper and the storage bucket which is communicated with the discharging hopper, so that the sliding cover can finish the operation of filling the die cavity in the reciprocating sliding process, and simultaneously finish the actions of raw material punching side forming, forming energy bar ejection and pushing, and the forming efficiency of the energy bar is improved; through setting up reciprocal gliding flexible scraper blade structure in the discharge hopper, flexible scraper blade passes through reciprocal drive assembly and conveying assembly linkage, can accomplish the even sharing of raw materials under the circumstances that does not additionally consume the electric energy, improves the degree of consistency of shaping energy stick, ensures that every energy stick specification is unified after the shaping.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is a schematic structural view of a stamping assembly;

FIG. 3 is a schematic diagram of a slider structure;

Fig. 4 is a schematic view of the connection structure of the parts on the hopper.

The numerical control device comprises the following components of 1, an operation table, 101, a groove, 102, a limit groove, 103, a chute, 104, a mounting hole, 2, a guide hopper, 3, a transmission shaft, 31, a spline, 4, a conveying belt, 5, a first motor, 6, a die holder, 61, a die cavity, 7, a punching component, 71, a telescopic rod, 72, a gravity sensor, 73, a mounting plate, 74, a punching head, 75, a hydraulic cylinder, 8, a sliding cover, 81, a limit block, 82, a through hole, 9, a linear die set, 10, a discharge hopper, 11, a weighing device, 12, a storage bucket, 121, a stirring component, 122, a feed hopper, 13, a discharge pipe, 131, a valve, 14, a movable plate, 15, a flexible scraping plate, 16, a reciprocating screw rod, 17, a first belt pulley, 18, a rotating shaft, 19, a second belt pulley, 20, a toothed belt, 21, a worm gear, 22 and a worm.

Detailed Description

Example 1

As shown in fig. 1 to 4, the energy bar forming device provided by the utility model comprises an operating platform 1, a punching assembly 7, a sliding cover 8, a reciprocating driving assembly, a transmission assembly, a weighing device 11 and a linear driving assembly. The operation panel 1 is provided with a groove 101, two ends of the operation panel 1 are respectively provided with a chute 103, a conveying component is arranged in each chute 103, the operation panel 1 is provided with a mounting hole 104 at the bottom of the groove 101, and the mounting hole 104 is internally provided with a die holder 6 with the upper end face flush with the bottom surface of the groove 101. The conveyor assembly comprises a drive shaft 3, a conveyor belt 4 and a first motor 5. The transmission shaft 3 includes two, and two transmission shafts 3 all rotate with operation panel 1 to be connected, and the symmetry sets up two driving rollers on the transmission shaft 3, and two driving rollers of both sides are located chute 103 of corresponding side respectively, and two driving rollers of homonymy are connected through a set of conveyer belt 4 transmission respectively, and the loading surface of conveyer belt 4 is not higher than the bottom surface of recess 101, and conveyer belt 4 is porous conveyer belt, and the body of first motor 5 is connected with operation panel 1, and the output and the one of them transmission shaft 3 of first motor 5 are connected. The two side openings of the chute on the operation table 1 are respectively provided with a guide hopper 2. The punching assembly 7 is provided at the bottom of the operation table 1, and the punching assembly 7 includes a telescopic rod 71, a punching head 74, a hydraulic cylinder 75, and a controller. The die holder 6 is provided with a plurality of die cavities 61, the bottom of the operating platform 1 is provided with a supporting frame, the body of the telescopic rod 71 is connected with the supporting frame, the movable end of the telescopic rod 71 is connected with the gravity sensor 72, the detection end of the gravity sensor 72 is connected with the mounting plate 73, the stamping heads 74 are connected with the mounting plate 73 and correspond to the die cavities 61 one by one, the body of the hydraulic cylinder 75 is connected with the supporting frame, and the output end of the hydraulic cylinder 75 is connected with the body of the gravity sensor 72. A controller is provided on the console 1, the controller is electrically connected to the gravity sensor 72, and the controller is controlled to connect with the hydraulic cylinder 75. The sliding cover 8 is arranged in the groove 101 in a sliding manner, the length of the sliding cover 8 is not smaller than three times of the length of the die holder 6 along the length direction of the groove 101, the length of the through hole 82 is the same as the length of the die holder 6, the through hole 82 matched with the die holder 6 is arranged on the sliding cover 8, the discharging hopper 10 matched with the through hole 82 is arranged on the sliding cover 8, the movable plate 14 is arranged in the discharging hopper 10 in a sliding manner, the flexible scraping plate 15 is arranged at the bottom of the movable plate 14, and the bottom surface of the flexible scraping plate 15 is in contact with the bottom surface of the groove 101. The reciprocating drive assembly includes a reciprocating screw 16. The reciprocating screw 16 is rotatably connected with the discharge hopper 10, and a shuttle of the reciprocating screw 16 is connected with the movable plate 14. The transmission assembly comprises a first pulley 17, a second pulley 19, a toothed belt 20, a worm wheel 21 and a worm 22. The transmission shaft 3 is provided with a spline 31, the discharge hopper 10 is provided with a fixed frame, the fixed frame is in sliding connection with the operation table 1, the end part of the reciprocating screw rod 16 is in rotary connection with the fixed frame, and the fixed frame is provided with a rotary shaft 18 in a rotary mode. The first belt wheel 17 is coaxially connected with the reciprocating screw rod 16, the second belt wheel 19 and the worm wheel 21 are coaxially connected with the rotating shaft 18, and the second belt wheel 19 and the first belt wheel 17 are in transmission connection through the toothed belt 20. The worm 22 is coaxially and slidably arranged on the transmission shaft 3 and the spline 31, the worm 22 is meshed with the worm wheel 21, and the transmission assembly is in transmission connection with the reciprocating driving assembly and the conveying assembly. The weighing device 11 is arranged on the sliding cover 8, the weighing device 11 is connected with the storage vat 12, the bottom of the storage vat 12 is provided with the discharging pipe 13, the discharging pipe 13 is inserted into the discharging hopper 10, and the discharging pipe 13 is provided with the valve 131. The weighing device 11 and the valve 131 are electrically connected with the controller. The linear driving assembly comprises, but is not limited to, a linear module 9, wherein the body of the linear module 9 is arranged on the operation table 1, the output end of the linear module 9 is connected with a sliding seat, the sliding seat is connected with a sliding cover 8, and the sliding seat is in sliding connection with the operation table 1.

In this embodiment, the mixed raw materials are put into a storage vat 12, at this time, a weighing device 11 weighs the storage vat 12 and the raw materials inside, then a valve 131 is opened and the raw materials are released, the total weight of the released raw materials is the total weight of the raw materials required to be added in all mold cavities 61, a linear mold set 9 drives a sliding cover 8 to slide, so that the outlet of a hopper 10 corresponds to a mold base 6, at this time, a conveying belt 4 operates, a transmission shaft 3 drives a worm 22 to rotate, the worm 22 drives a worm wheel 21, a rotating shaft 18 and a second belt wheel 19 to rotate, a first belt wheel 17 and a reciprocating screw 16 are driven to rotate by a toothed belt 20, then a movable plate 14 and a flexible scraping plate 15 are driven to slide reciprocally by the reciprocating screw 16, the raw materials in the discharge hopper 10 are uniformly spread into each mold cavity 61 by the flexible scraping plate 15 which slides reciprocally, then the sliding cover 8 slides to enable the bottom surface on one side to seal the upper end opening of the mold cavity 61, then the hydraulic cylinder 75 pushes up the body of the gravity sensor 72, and then drives the mounting plate 73 and the punching head 74 to rise, the punching head 74 cooperates with the sliding cover 8 to extrude and shape the raw materials in the die cavity 61, then the sliding cover 8 slides to the upper end opening of the die cavity 61 to expose, the hydraulic cylinder 75 continues to push up the punching head 74 to push out the formed energy rod, then the sliding cover 8 slides back and pushes the energy rod onto the conveyor belt 4 in front of the running direction, scraps are separated from the energy rod, and in the process of sliding cover 8 sliding back and pushing out the formed energy rod, the punching head 74 slides down and resets, the die cavity 61 is restored to the idle state again, at the moment, the discharge hopper 10 corresponds to the die cavity 61 for the second time, and then secondary filling is directly carried out, and after filling is completed, the sliding cover 8 slides back again, so that the whole device completes twice filling, distributing, sorting, and the stamping and discharging actions greatly improve the processing efficiency of the energy rod.

Example two

As shown in fig. 1, in the energy bar forming apparatus according to the present utility model, compared with the first embodiment, a stirring assembly 121 and a feed hopper 122 are disposed in a storage barrel 12, the stirring assembly 121 includes a second motor and a stirring paddle, a stirring shaft is disposed on a barrel cover of the storage barrel 12, a body of the second motor is connected with the barrel cover, an output end of the second motor is connected with the stirring shaft, and the stirring paddle is disposed on the stirring shaft.

In this embodiment, the stirring shaft and the stirring paddle are driven by the second motor to rotate, so that uniformity of the raw materials in the storage barrel 12 can be ensured, and the raw materials in the storage barrel 12 can be prevented from blocking the discharge pipe 13 when descending.

Example III

As shown in fig. 1 and 3, compared with the first embodiment, the energy bar forming device provided by the utility model has a limiting groove 102 on two sides of the groove 101 on the console 1, a limiting block 81 on two ends of the sliding cover 8, and each limiting block 81 is inserted into and slidably connected with the corresponding limiting groove 102.

In this embodiment, the matching structure of the limiting groove 102 and the limiting block 81 makes the sliding of the sliding cover 8 more stable, and further improves the impact-pressure resistance of the sliding cover 8.

The embodiments of the present utility model have been described in detail with reference to the drawings, but the present utility model is not limited thereto, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present utility model.

Claims (7)

1. An energy bar forming apparatus comprising

The automatic feeding device comprises an operation table (1), wherein a groove (101) is formed in the operation table (1), two inclined grooves (103) are respectively formed in two ends of the operation table (1), a conveying assembly is arranged in each inclined groove (103), and a die holder (6) with the upper end face being flush with the bottom surface of the groove (101) is arranged on the operation table (1);

the stamping component (7), the stamping component (7) is arranged at the bottom of the operating platform (1) and is matched with the die holder (6);

The sliding cover (8) is arranged in the groove (101) in a sliding way, a through hole (82) matched with the die holder (6) is formed in the sliding cover (8), a discharge hole and a discharge hopper (10) matched with the through hole (82) are formed in the sliding cover (8), a movable plate (14) is arranged in the discharge hopper (10) in a sliding way, a flexible scraping plate (15) is arranged at the bottom of the movable plate (14), and the bottom surface of the flexible scraping plate (15) is in contact with the bottom surface of the groove (101);

the reciprocating driving assembly is arranged on the discharge hopper (10) and is in driving connection with the movable plate (14);

The transmission assembly is in transmission connection with the reciprocating driving assembly and the conveying assembly;

The weighing device (11), the weighing device (11) is arranged on the sliding cover (8), the weighing device (11) is connected with the storage vat (12), the bottom of the storage vat (12) is provided with the discharging pipe (13), the discharging pipe (13) is inserted into the discharging hopper (10), and the discharging pipe (13) is provided with the valve (131);

And the linear driving assembly is arranged on the operating platform (1) and is in driving connection with the sliding cover (8).

2. The energy rod forming device according to claim 1, wherein the conveying assembly comprises two transmission shafts (3), a conveying belt (4) and a first motor (5), the two transmission shafts (3) are rotationally connected with the operation table (1), two transmission rollers are symmetrically arranged on the transmission shafts (3), the transmission rollers on the two sides are respectively located in a chute (103) on the corresponding side, the two transmission rollers on the same side are respectively in transmission connection through a group of the conveying belt (4), a body of the first motor (5) is connected with the operation table (1), and the output end of the first motor (5) is connected with one transmission shaft (3).

3. An energy bar forming apparatus according to claim 2, wherein the reciprocating drive assembly comprises a reciprocating screw (16), the reciprocating screw (16) being rotatably connected to the discharge hopper (10), the shuttle of the reciprocating screw (16) being connected to the movable plate (14).

4. An energy rod forming device according to claim 3, characterized in that the transmission assembly comprises a first belt wheel (17), a second belt wheel (19), a toothed belt (20), a worm wheel (21) and a worm (22), wherein a spline (31) is arranged on the transmission shaft (3), a fixed frame is arranged on the discharge hopper (10), the fixed frame is in sliding connection with the operation table (1), the end part of the reciprocating screw (16) is in rotating connection with the fixed frame, a rotating shaft (18) is arranged on the fixed frame in rotating connection with the reciprocating screw (16), the first belt wheel (17) is in coaxial connection with the reciprocating screw (16), the second belt wheel (19) and the worm wheel (21) are in coaxial connection with the rotating shaft (18), the second belt wheel (19) and the first belt wheel (17) are in transmission connection through the toothed belt (20), the worm (22) is in coaxial sliding connection with the transmission shaft (3) and the spline (31), and the worm (22) is meshed with the worm wheel (21).

5. The energy rod forming device according to claim 1, wherein the stamping assembly (7) comprises a telescopic rod (71), a stamping head (74), a hydraulic cylinder (75) and a controller, a plurality of die cavities (61) are formed in a die holder (6), a supporting frame is arranged at the bottom of the operating table (1), a body of the telescopic rod (71) is connected with the supporting frame, a movable end of the telescopic rod (71) is connected with a gravity sensor (72), a detection end of the gravity sensor is connected with a mounting plate (73), the stamping head (74) is connected with the mounting plate (73) and corresponds to the die cavities (61) one by one, a body of the hydraulic cylinder (75) is connected with the supporting frame, an output end of the hydraulic cylinder (75) is connected with a body of the gravity sensor (72), the controller is arranged on the operating table (1), and the controller is electrically connected with the gravity sensor (72) and is controlled to be connected with the hydraulic cylinder (75).

6. An energy bar forming machine according to claim 5, characterized in that the weighing machine (11) and the valve (131) are electrically connected to the controller.

7. The energy rod forming equipment according to claim 1, wherein a stirring assembly (121) and a feed hopper (122) communicated with the interior of the stirring assembly are arranged in the storage barrel (12), the stirring assembly (121) comprises a second motor and a stirring paddle, a stirring shaft is arranged on a barrel cover of the storage barrel (12), a body of the second motor is connected with the barrel cover, an output end of the second motor is connected with the stirring shaft, and the stirring paddle is arranged on the stirring shaft.