CN113831968B - Automatic core sticking machine for canned candle production line - Google Patents

Abstract

The invention relates to the technical field of canned candle production devices, in particular to an automatic core sticking machine for a canned candle production line; by constructing a lifting synchronous lifting table above the conveyor belt, the lifting synchronous lifting table can be well embedded into an automatic production line, and is matched with an adjustable core pressing mechanism driven by a linear motor, so that the adjustment of parameters of canned artistic candles with different specifications is facilitated, the lifting synchronous lifting table is suitable for wax cores with different lengths, the core sticking process is automatically completed, the labor cost is reduced for enterprises, the production efficiency is improved, and the working environment is improved; the processes of iron button feeding, wax core conveying and core pressing are respectively completed by using the air cylinder, the stepping motor, the synchronous belt transmission and the linear motor, so that the machine is quick, accurate and high in reliability, the mechanical structure is simplified, and the machine has the advantages of convenience in air source, small pollution and the like; the connection part of the stepping motor and the driving shaft of the synchronous belt is connected through a connecting shaft device with a one-way bearing, so that the speed synchronization in the core pressing process can be realized, and the complexity of a control system is greatly simplified.

Description

Automatic core sticking machine for canned candle production line

Technical Field

The invention relates to the technical field of canned candle production devices, in particular to an automatic core sticking machine for a canned candle production line.

Background

With the increasing level of living of people, candles have become artware from life necessities. Therefore, people pursue the shape and color of candles, enterprises push out different types of canned art candles in order to meet the needs of consumers, and canned art candles are one of the most popular products. Meanwhile, along with the continuous improvement of automation level and labor cost in China, more and more candle manufacturers are added into automation transformation, and the automatic production of canned artistic candles is hoped. The great difficulty is how to realize the automation of the processes of core penetration, buckling and sticking of the wax core.

At present, the wax core sticking mode mainly comprises the following steps:

first, the core is glued directly by hand. The method is to use automatic sandwich equipment to complete the process of threading and button making, and then glue the wax core threaded with the iron button manually and adhere the wax core to the bottle bottom. When the method is used for sticking the core, the defects of core offset, core sticking non-work, low production efficiency and the like are often caused by manual reasons.

Second, the demolding candle assists in penetrating the wick. The method comprises the steps of using an automatic core penetrating machine to penetrate and fix the pressed and demoulded paraffin, and then using a special guiding tool to adhere the demoulded paraffin and the paraffin core to the bottom of the bottle after manual collection. The technology solves the offset problem of the artificial sticking core and improves the production efficiency, but the specification of the canned artistic candles produced by the method is limited by the specification of the demolding candles, and meanwhile, the candles produced by the method are not in accordance with the requirements of customers with gram weight.

Thirdly, an indexing type automatic core sticking machine sticks cores. The method is characterized in that a magnetic guide pipe is used for sucking a iron buckle, a core conveying mechanism is used for finishing core penetrating of a wax core through the iron buckle from bottom to top, and a guide pipe penetrates into the bottom of a bottle after the wax core is clamped in place by a guide pipe bottom clamping mechanism, so that core sticking is finished. Such a process has been done in-line with the sticking process, but due to the limitations of the indexing device, the specification limitations for canned candles remain, and high flexibility production of canned candles cannot be achieved.

At present, the main technical problems are that in three processes of perforation, buckling and core pressing of a wax core, on one hand, manual operation is reduced as much as possible in the core sticking process, the labor intensity of workers is reduced, and the degree of automation is improved. On the other hand, when the wax core is stuck, the positioning is accurate, the sticking is firm, and the sticking reliability is high.

Therefore, the inventor designs an automatic core sticking machine for a canned candle production line, which is used for solving the problems.

Disclosure of Invention

(one) solving the technical problems

The invention aims to overcome the defects in the prior art and provides an automatic core sticking machine for a canned candle production line.

(II) technical scheme

An automatic core sticking machine for a canned candle production line comprises a synchronous lifting table, a feeding mechanism, a core conveying mechanism, a clamping and shearing mechanism, a conveyor belt and a core pressing mechanism; the synchronous lifting platform is positioned above the conveyor belt; the feeding mechanism, the core conveying mechanism, the clamping and shearing mechanism and the core pressing mechanism are all fixed on the synchronous lifting platform;

and the synchronous lifting platform is also provided with a dispensing mechanism.

Preferably, the feeding mechanism is used for conveying the iron buckle to the core conveying mechanism so as to finish feeding, and comprises a guide rail, a feeding plate, an air cylinder, a vibration disc and a feeding device;

the guide rail is fixed on the synchronous lifting platform, and the feeding plate is arranged on the guide rail and is powered by the air cylinder to move; the vibration disc is arranged on one side of the guide rail and is provided with a conveying track extending into the conveying device; the feeding plate is provided with a round permanent magnet for automatically centering the iron buckle.

Preferably, the bottom surface of the material conveying device is tightly adhered to the surface of the material loading plate; the feeding plate is provided with a U-shaped groove and has a certain gap with the material conveying device.

Preferably, the core conveying mechanism is used for conveying the wax core into the iron buckle so as to finish core conveying, and comprises a synchronous belt, a supporting plate, a triangular support frame and a guide device fixing clamp;

the supporting plate is fixed on the synchronous lifting platform through the triangular support frame; the supporting plate is provided with symmetrical synchronous belts; the supporting plate is also provided with a guiding device fixing clamp for fixing the guiding device.

Preferably, the supporting plate is also provided with an adjusting support, a fixing block and a tensioning wheel; the take-up pulley sets up in the hold-in range outside, and the take-up pulley dress is on adjusting the support, adjusts the support and can remove and fix along the backup pad.

Preferably, the synchronous belt comprises a one-way bearing, a gear, a synchronous belt driving shaft, a synchronous belt wheel, an expanding sleeve, a synchronous belt body, a bearing seat, a sleeve, a stepped shaft, a bearing and a screw;

the synchronous belt body is arranged on one side of the supporting plate, and the two ends are in transmission connection through a synchronous belt pulley; one end of the synchronous pulley is connected with a synchronous belt driving shaft through an expansion sleeve, the other end of the synchronous pulley is connected with a stepped shaft through a sleeve, and the stepped shaft is arranged on the supporting plate through a bearing seat, a bearing and a screw;

the two synchronous belt driving shafts are correspondingly provided with gears meshed with each other, and one synchronous belt driving shaft is connected with a stepping motor through a one-way bearing and used for obtaining fixed steering power.

Preferably, the clamping and shearing mechanism is used for clamping the iron buckle with the completed core penetrating and shearing the wax core and comprises a shearing cylinder, a clamping cylinder, a shearing tool and a shearing cylinder supporting seat; the shearing cylinder is fixed on the synchronous lifting platform through a shearing cylinder supporting seat; the cutting cylinder is connected with the cutting tool and controls the movement of the cutting tool; the clamping cylinder is also fixed on the synchronous lifting platform.

Preferably, the pressing mechanism is used for pressing the wax core into the bottle bottom so as to finish pressing the core, and comprises a mounting seat, a linear motor, a connecting plate, a pressing rod and a pressing rod mounting block; the installation seat is fixed on the synchronous lifting platform, and the compression bar is installed on the installation seat through the connection plate and the compression bar installation block and is powered by the linear motor to move.

Preferably, the dispensing mechanism is controlled by a detection signal of a photoelectric sensor; when the conveyor belt passes through the glass bottle, the photoelectric sensor detects and starts dispensing, and after dispensing, core conveying, feeding, clamping, core pressing and cutting are sequentially started under beat matching to finish core sticking; when the last glass bottle finishes sticking the core, the comparator triggers M > N, the photoelectric sensor can not detect that an object passes, and the follow-up core conveying, feeding, core penetrating and core pressing can not continue to work.

(III) beneficial effects

The invention provides an automatic core sticking machine for a canned candle production line, which has the following advantages:

1, by constructing a lifting synchronous lifting table above a conveyor belt, the lifting synchronous lifting table can be well embedded into an automatic production line, and is matched with an adjustable core pressing mechanism driven by a linear motor, so that parameters of canned artistic candles with different specifications can be conveniently adjusted, the lifting synchronous lifting table is suitable for wax cores with different lengths, the core sticking process is automatically completed, the labor cost is reduced for enterprises, the production efficiency is improved, and the working environment is improved;

secondly, the processes of iron button feeding, wax core conveying and core pressing are respectively completed by using the air cylinder, the stepping motor, the synchronous belt transmission and the linear motor, so that the machine is quick, accurate and high in reliability, the mechanical structure is simplified, and the machine has the advantages of convenience in air source, small pollution and the like.

Thirdly, the junction of the stepping motor and the driving shaft of the synchronous belt is connected through a connecting shaft device with a one-way bearing, so that the speed synchronization in the core pressing process can be realized, and the complexity of a control system is greatly simplified.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only of the present invention, protecting some embodiments, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is an overall block diagram of the present invention;

FIG. 2 is a block diagram of a core handling mechanism;

FIG. 3 is a block diagram of a synchronous belt;

fig. 4 is a structural view of a feeding mechanism;

FIG. 5 is a block diagram of a clamping and shearing mechanism;

FIG. 6 is a block diagram of a core pressing mechanism;

fig. 7 is a workflow diagram.

In the drawings, the list of components represented by the various numbers is as follows:

11-synchronous lifting table, 12-core conveying mechanism, 13-feeding mechanism, 14-clamping and shearing mechanism, 15-conveyor belt, 16-core pressing mechanism and 17-dispensing mechanism;

21-synchronous belt, 22-adjusting support, 23-fixing block, 24-supporting plate, 25-tensioning wheel, 26-triangular support frame and 27-guiding device fixing clamp;

31-one-way bearings, 32-gears, 33-synchronous belt driving shafts, 34-synchronous pulleys, 35-expansion sleeves, 36-synchronous belt bodies, 37-bearing seats, 38-sleeves, 39-stepped shafts, 310-bearings and 311-screws;

41-guide rails, 42-feeding plates, 43-cylinders, 44-vibration plates and 45-material conveying devices;

51-shearing cylinder, 52-clamping cylinder, 53-shearing tool, 54-shearing cylinder support seat;

61-mount pad, 62-linear electric motor, 63-connecting plate, 64-depression bar, 65-depression bar installation piece.

Detailed Description

The following description of the embodiments of the present invention will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the invention are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be noted that, if terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like are used, the indicated orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, only for convenience of describing the present invention and simplifying the description, and does not indicate or imply that the indicated apparatus or element must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like, as used herein, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that unless explicitly specified and limited otherwise, terms such as "mounted," "connected," and "connected" are to be construed broadly and include, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

The invention relates to an automatic core sticking machine for a canned candle production line, which consists of a synchronous lifting table 11, a feeding mechanism 13, a core conveying mechanism 12, a clamping and shearing mechanism 14, a conveyor belt 15 and a core pressing mechanism 16, wherein the synchronous lifting table 11 is positioned above the conveyor belt 15 as shown in figure 1; the feeding mechanism 13, the core conveying mechanism 12, the clamping and shearing mechanism 14 and the core pressing mechanism 16 are all fixed on the synchronous lifting table 11.

The feeding mechanism 13 is used for conveying iron buckles to the core conveying mechanism 12 to finish feeding, and comprises a guide rail 41, a feeding plate 42, an air cylinder 43, a vibration disc 44 and a feeding device 45;

as shown in fig. 4, a guide rail 41 is fixed on the synchronous lifting table 11, and a feeding plate 42 is mounted on the guide rail 41 and is powered by an air cylinder 43 to move; the vibration disk 44 is arranged on one side of the guide rail 41 and is provided with a material conveying track extending into the material conveying device 45; the loading plate 42 is provided with a circular permanent magnet for automatically centering the iron buckle.

In this way, the iron buttons enter the material conveying device 45 through the vibration disc 44 and the corresponding material conveying track, the bottom surface of the material conveying device 45 is tightly adhered to the surface of the material feeding plate 42, the material feeding plate 42 is provided with a U-shaped groove, a certain gap exists between the material feeding plate and the material conveying device 45, the iron buttons regularly arranged on the material conveying device 45 fall under the action of gravity, the magnetic force of the round permanent magnets on the material feeding plate 42 automatically centers after falling, and then the air cylinder 43 drives the material feeding plate 42 to move forwards to finish material feeding;

the core conveying mechanism 12 is used for conveying wax cores into the iron buttons so as to complete core conveying, and comprises a synchronous belt 21, a supporting plate 24, a triangular support frame 26 and a guiding device fixing clamp 27;

as shown in fig. 2, the support plate 24 is fixed to the synchronous lifting table 11 by a tripod 26; the supporting plate 24 is provided with symmetrical synchronous belts 21; the support plate 24 is further provided with a guide fixing clip 27 for fixing the guide.

The supporting plate 24 is also provided with an adjusting support 22, a fixed block 23 and a tensioning wheel 25; the tensioning wheel 25 is arranged outside the synchronous belt 21, the tensioning wheel 25 is arranged on the adjusting support 22, and the adjusting support 22 can move along the supporting plate 24 and be fixed, so that the tensioning wheel 25 can tension the synchronous belt 21.

As shown in fig. 3, the timing belt 21 includes a one-way bearing 31, a gear 32, a timing belt driving shaft 33, a timing pulley 34, an expanding sleeve 35, a timing belt body 36, a bearing housing 37, a sleeve 38, a stepped shaft 39, a bearing 310, and a screw 311;

the synchronous belt body 36 is arranged on one side of the supporting plate 24, and the two ends are in transmission connection through the synchronous belt pulley 34; the synchronous pulley 34 at one end is connected with a synchronous belt driving shaft 33 through an expanding sleeve 35, the synchronous pulley 34 at the other end is connected with a stepped shaft 39 through a sleeve 38, and the stepped shaft 39 is arranged on the supporting plate 24 through a bearing seat 37, a bearing 310 and a screw 311;

two synchronous belt driving shafts 33 are correspondingly provided with gears 32 meshed with each other, wherein one synchronous belt driving shaft 33 is connected with a stepping motor through a one-way bearing 31 and used for obtaining fixed steering power.

The stepping motor makes the synchronous belt driving shaft 33 obtain the power of fixed steering through the one-way bearing 31, and transmits the power to the other synchronous belt driving shaft 33 through the gear 32, so that the two synchronous belts 21 keep the speed synchronization. The synchronous belt driving shaft 33 transmits power to the synchronous belt body 36 through the synchronous belt pulley 34 and the expansion sleeve 35, and the stepped shaft 39 realizes the operation of the synchronous belt body 36 by utilizing the sleeve 38 and the corresponding belt pulley.

In this way, the wax core penetrates into the guiding device fixed by the guiding device fixing clamp 27 through the friction force between the synchronous belts 21, and the wax core penetrates into the iron buckle under the guiding of the guiding device to finish the core conveying work;

the clamping and shearing mechanism 14 is used for clamping the iron buckle with the core penetrating completed and shearing the wax core, and comprises a shearing cylinder 51, a clamping cylinder 52, a shearing cutter 53 and a shearing cylinder supporting seat 54;

as shown in fig. 5, the shear cylinder 51 is fixed to the synchronous lift table 11 by a shear cylinder support block 54; the cutting cylinder 51 is connected with the cutting tool 53 and controls the movement of the cutting tool 53; the clamping cylinder 52 is also fixed to the synchronous lifting table 11.

The pressing mechanism is used for pressing the wax core into the bottle bottom to finish core pressing and comprises a mounting seat 61, a linear motor 62, a connecting plate 63, a pressing rod 64 and a pressing rod mounting block 65;

as shown in fig. 6, the mount 61 is fixed to the synchronous lifting table 11, and the presser bar 64 is mounted on the mount 61 via the connection plate 63 and the presser bar mounting block 65, and is moved by the power of the linear motor 62.

Thus, after the wax core penetrates into the iron buckle, the opposite clamping air cylinders 52 synchronously move under the control of the synchronous speed pneumatic control loop, and the clamping blocks in front of the clamping air cylinders 52 clamp the iron buckle to finish clamping; simultaneously, the feeding plate 42 is retracted, the clamping cylinder 52 is opened, the pressing mechanism 16 starts to act, the linear motor 62 moves the pressing rod 64, and the wax core is pressed into the bottle bottom under the action of the pressing rod, so that core pressing is completed; then, the cutting cylinder 51 drives the cutting tool 53 to start to perform cutting.

In actual operation, the above-mentioned operation needs to be combined with the dispensing operation, so that the synchronous lifting table 11 is further provided with a dispensing mechanism 17 and is controlled by the detection signal of the photoelectric sensor.

Referring to fig. 7, parameters such as height and diameter are input according to the product specification to complete the lifting of the synchronous lifting table 11, and then the conveyor belt 15 is started; the conveyor belt 15 carries glass bottles to pass through, the photoelectric sensor detects and starts dispensing, after dispensing, core conveying, feeding, clamping, core pressing and cutting (namely, core conveying, iron button conveying, core penetrating and button pressing and bottle bottom pressing in the drawings) are sequentially started to work under beat matching, and core sticking is completed; when the last glass bottle finishes sticking the core, the comparator triggers M > N, the photoelectric sensor can not detect that an object passes, and the follow-up core conveying, feeding, core penetrating and core pressing can not continue to work.

In addition, an emergency stop button is provided in the machine to allow emergency stop in the event of accident.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (3)

1. The automatic core sticking machine for the canned candle production line is characterized by comprising a synchronous lifting table (11), a feeding mechanism (13), a core conveying mechanism (12), a clamping and shearing mechanism (14), a conveyor belt (15) and a core pressing mechanism (16); the synchronous lifting platform (11) is positioned above the conveyor belt (15); the feeding mechanism (13), the core conveying mechanism (12), the clamping and shearing mechanism (14) and the core pressing mechanism (16) are all fixed on the synchronous lifting table (11);

the feeding mechanism (13) is used for conveying the iron buckle to the core conveying mechanism (12) so as to finish feeding, and comprises a guide rail (41), a feeding plate (42), an air cylinder (43), a vibration disc (44) and a feeding device (45); the guide rail (41) is fixed on the synchronous lifting table (11), and the feeding plate (42) is arranged on the guide rail (41) and is powered by the air cylinder (43) to move; the vibration disc (44) is arranged at one side of the guide rail (41) and is provided with a material conveying track extending into the material conveying device (45); a circular permanent magnet is arranged on the feeding plate (42) and used for automatically centering the iron buckle; the bottom surface of the material conveying device (45) is closely attached to the surface of the material loading plate (42); the feeding plate (42) is provided with a U-shaped groove and has a certain gap with the material conveying device (45);

the synchronous belt (21) comprises a one-way bearing (31), a gear (32), a synchronous belt driving shaft (33), a synchronous pulley (34), an expansion sleeve (35), a synchronous belt body (36), a bearing seat (37), a sleeve (38), a stepped shaft (39), a bearing (310) and a screw (311); the synchronous belt body (36) is arranged on one side of the supporting plate (24), and the two ends are in transmission connection through the synchronous belt wheel (34); one end of the synchronous pulley (34) is connected with a synchronous belt driving shaft (33) through an expanding sleeve (35), the other end of the synchronous pulley (34) is connected with a stepped shaft (39) through a sleeve (38), and the stepped shaft (39) is arranged on the supporting plate (24) through a bearing seat (37), a bearing (310) and a screw (311); the two synchronous belt driving shafts (33) are correspondingly provided with gears (32) engaged, wherein one synchronous belt driving shaft (33) is connected with a stepping motor through a one-way bearing (31) and is used for obtaining fixed steering power;

the core pressing mechanism (16) is used for pressing the wax core into the bottle bottom to finish core pressing and comprises a mounting seat (61), a linear motor (62), a connecting plate (63), a pressing rod (64) and a pressing rod mounting block (65); the mounting seat (61) is fixed on the synchronous lifting table (11), and the compression bar (64) is mounted on the mounting seat (61) through the connecting plate (63) and the compression bar mounting block (65) and is powered by the linear motor (62) to move;

the core conveying mechanism (12) is used for conveying wax cores into the iron buttons so as to finish core conveying, and comprises a synchronous belt (21), a supporting plate (24), a triangular support frame (26) and a guiding device fixing clamp (27); the supporting plate (24) is fixed on the synchronous lifting platform (11) through a triangular supporting frame (26); the supporting plate (24) is provided with symmetrical synchronous belts (21); the supporting plate (24) is also provided with a guiding device fixing clamp (27) for fixing the guiding device;

a dispensing mechanism (17) is further arranged on the synchronous lifting table (11), and the dispensing mechanism (17) is controlled by a detection signal of a photoelectric sensor; when the conveyor belt (15) carries glass bottles to pass, the photoelectric sensor detects and starts dispensing, and after dispensing, core conveying, feeding, clamping, core pressing and cutting are sequentially started under beat matching, so that core sticking is completed; when the last glass bottle finishes sticking the core, the comparator triggers M > N, the photoelectric sensor can not detect that an object passes, and the follow-up core conveying, feeding, core penetrating and core pressing can not continue to work.

2. The automatic core bonding machine for the canned candle production line according to claim 1, wherein the supporting plate (24) is also provided with an adjusting support (22), a fixed block (23) and a tensioning wheel (25); the tensioning wheel (25) is arranged on the outer side of the synchronous belt (21), the tensioning wheel (25) is arranged on the adjusting support (22), and the adjusting support (22) can move along the supporting plate (24) and be fixed.

3. The automatic core sticking machine for the canned candle production line according to claim 1, wherein the clamping and shearing mechanism (14) is used for clamping a core-penetrating iron buckle and shearing a wax core, and comprises a shearing cylinder (51), a clamping cylinder (52), a shearing cutter (53) and a shearing cylinder supporting seat (54); the shearing cylinder (51) is fixed on the synchronous lifting table (11) through a shearing cylinder supporting seat (54); the cutting cylinder (51) is connected with the cutting tool (53) and controls the movement of the cutting tool (53); the clamping cylinder (52) is also fixed on the synchronous lifting platform (11).