CN218018694U - Numerical control silica gel smoothing mill - Google Patents

Abstract

The utility model discloses a numerical control silica gel smoothing mill, including horn mouth, gear feeding mechanism A, fly cutter cutting structure, gear feeding mechanism B, material feeding mouth, baffle, branch material wheel and conveyer belt, gear feeding mechanism A and gear feeding mechanism B pass through the bolt and install on the workstation, and the input/output end of gear feeding mechanism A and the input/output end of gear feeding mechanism B are coaxial to be set up, and wherein the input of gear feeding mechanism A passes through the charge-in pipeline and connects the horn mouth, installs fly cutter cutting structure between the output of gear feeding mechanism A and the input of gear feeding mechanism B; this practicality can realize cutting off in succession of silica gel stick through setting up round feeding mechanism A, fly sword cutting structure, gear feeding mechanism B, can realize the control of length output through control wheel feeding mechanism A, and the silica gel stick after cutting off in addition can be carried and divides material wheel department and output on by comparatively orderly arrangement to the conveyer belt, and overall structure is comparatively simple.

Description

Numerical control silica gel finishing machine

Technical Field

The utility model relates to a smoothing mill specifically is a numerical control silica gel smoothing mill.

Background

The silica gel stick has wide application, and the newly produced silica gel stick is a product with very long whole length, needs to be divided into shorter sections during subsequent sale and is also beneficial to packaging; at present, small and medium-sized enterprises in silica gel rod production generally adopt a manual cutting mode for processing, so that manual production is improved into mechanical production, and cost reduction and sustainable development of the enterprises are facilitated.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a simple structure's numerical control silica gel smoothing mill.

In order to achieve the above object, the utility model provides a following technical scheme:

a numerical control silica gel precision cutting machine comprises a bell mouth, a gear feeding mechanism A, a fly cutter cutting structure, a gear feeding mechanism B, a feeding nozzle, a baffle, a material distribution wheel and a conveyor belt, wherein the gear feeding mechanism A and the gear feeding mechanism B are installed on a workbench through bolts, the input and output ends of the gear feeding mechanism A and the input and output ends of the gear feeding mechanism B are coaxially arranged, the input end of the gear feeding mechanism A is connected with the bell mouth through a feeding pipeline, the fly cutter cutting structure is installed between the output end of the gear feeding mechanism A and the input end of the gear feeding mechanism B, the output end of the gear feeding mechanism B is connected with one end of the feeding nozzle, and the other end of the feeding nozzle faces the material distribution wheel; the rotating shaft of the distributing wheel is rotatably arranged on the machine frames at two sides of the conveying belt through a bearing and a bearing seat, one end of the rotating shaft of the distributing wheel is connected with a driving motor through a belt transmission mechanism, the driving motor can be fixedly connected to the bottom of the machine frame of the conveying belt, and the rotating direction of the distributing wheel is opposite to the moving direction of the belt body of the conveying belt; a baffle is arranged on one side of the material distribution wheel, which faces downwards in the rotating direction, the baffle is of a cambered surface structure corresponding to the surface of the material distribution wheel, and a silica gel rod can be accommodated between the baffle and a notch formed in the surface of the material distribution wheel along the axial direction; the baffle is fixedly connected to the racks on the two sides of the conveyor belt through the bracket of the baffle;

preferably, the following components: the lower edge of the baffle is tangent to the surface of the belt body of the conveying belt.

Preferably: the gear feeding mechanism A and the gear feeding mechanism B respectively comprise a shell and a group of feeding gears which are rotatably connected in the shell, a space for a silica gel rod to pass through is arranged between the two feeding gears, one ends of the two feeding gears, which are positioned outside, are respectively connected with two transmission gears which are meshed with each other, and the transmission gears are meshed with a driving gear on the output end of a motor with the surface fixed on the shell.

Preferably, the following components: the fly cutter cutting structure also comprises a corresponding driving motor and a corresponding cutting cutter, the driving motor is fixedly connected to the workbench, and an output shaft of the driving motor is fixedly connected with one end of the cutting cutter.

Preferably, the following components: the uppermost part of the material distributing wheel is provided with a pressing strip, two ends of the pressing strip are respectively and fixedly connected to the bearing seat and the material feeding nozzle, and the output rubber rod is pressed in a surface notch of the material distributing wheel through the pressing strip.

Due to the adoption of the technical scheme, the utility model discloses following superiority has: this practicality can realize cutting off in succession of silica gel stick through setting up round feeding mechanism A, fly cutter cutting structure, gear feeding mechanism B, can realize the control of length output through control wheel feeding mechanism A, and the silica gel stick after cutting off in addition can be carried and divides material wheel department and output on being comparatively neatly arranged the conveyer belt, and overall structure is comparatively simple.

Drawings

FIG. 1 is a schematic structural diagram of a numerical control silica gel precision cutting machine.

Fig. 2 is an enlarged schematic view of a portion a in fig. 1.

Fig. 3 is an enlarged schematic view of a portion B in fig. 1.

In the figure: the device comprises a bell mouth 1, a gear feeding mechanism A2, a human-computer interface 3, a fly cutter cutting structure 4, a gear feeding mechanism B5, a feeding nozzle 6, a baffle 7, a material distributing wheel 8, a conveying belt 9 and a pressing strip 10.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.

Referring to fig. 1 to 3, in an embodiment of the present invention, a numerical control silica gel precision cutting machine includes a bell mouth 1, a gear feeding mechanism A2, a human-computer interface setting 3, a fly cutter cutting structure 4, a gear feeding mechanism B5, a feeding nozzle 6, a baffle 7, a material distribution wheel 8 and a conveyor belt 9, wherein the gear feeding mechanism A2 and the gear feeding mechanism B5 are mounted on a workbench through bolts, an input/output end of the gear feeding mechanism A2 and an input/output end of the gear feeding mechanism B5 are coaxially arranged, an input end of the gear feeding mechanism A2 is connected with the bell mouth 1 through a feeding pipeline, the fly cutter cutting structure 4 is mounted between an output end of the gear feeding mechanism A2 and an input end of the gear feeding mechanism B5, an output end of the gear feeding mechanism B5 is connected with one end of the feeding nozzle 6, and the other end of the feeding nozzle 6 faces the material distribution wheel 8;

the rotating shaft of the distributing wheel 8 is rotatably mounted on the racks at two sides of the conveying belt 9 through a bearing and a bearing seat (the conveying direction of the conveying belt 9 is perpendicular to the space of the conveying direction of the gear feeding mechanism B5), one end of the rotating shaft of the distributing wheel 8 is connected with a driving motor through a belt transmission mechanism, the driving motor can be fixedly connected to the bottom of the rack of the conveying belt 9 to realize the driving of the distributing wheel 8, and the rotating direction of the distributing wheel 8 is opposite to the moving direction of the belt body of the conveying belt; a baffle 7 is arranged on one side of the material distribution wheel 8, which faces downwards, the baffle 7 is of a cambered surface structure corresponding to the surface of the material distribution wheel 8, and a silica gel rod can be accommodated between notches formed in the surfaces of the baffle 7 and the material distribution wheel 8 along the axial direction; the baffle 7 is fixedly connected to the racks on the two sides of the conveyor belt 9 through the bracket, when a material bar is conveyed into the notch on the surface of the material distribution wheel 8, the material bar moves downwards along with the rotation of the material distribution wheel 8, and finally is output onto the conveyor belt from the lowest edge of the baffle 7, so that the blanking stability and the relative neatness in arrangement are ensured;

the lower edge of the baffle 7 is tangent to the surface of the conveyor belt body.

The gear feeding mechanism A2 and the gear feeding mechanism B5 both comprise a shell and are rotatably connected with a group of feeding gears in the shell, a space for a silica gel rod to pass through is formed between the two feeding gears, one ends, located outside, of shafts of the two feeding gears are respectively connected with two transmission gears which are meshed with each other, and the transmission gears are meshed with a driving gear on the output end of a motor with the surface fixed on the shell so as to control the rotation of the feeding gears in the motor to further realize the conveying of the silica gel rod through friction.

The fly cutter cutting structure 4 also comprises a corresponding driving motor and a corresponding cutting-off cutter, the driving motor is fixedly connected to the workbench, an output shaft of the driving motor is fixedly connected with one end of the cutting-off cutter, and the cutting-off cutter is driven to rotate through the motor so as to cut off the material rod.

The uppermost part of the material distribution wheel 8 is provided with a pressing strip 10, two ends of the pressing strip 10 are respectively and fixedly connected to the bearing seat and the feeding nozzle 6, and the output rubber rod is ensured to be pressed in a surface groove of the material distribution wheel 8 through the pressing strip 10.

In this application, gear feeding mechanism A2, fly cutter cut off structure 4, gear feeding mechanism B5, divide the driving motor of material wheel 8, conveyer belt 9 all to be controlled by human-computer interface 3, its control circuit adopt prior art can, this application is not repeated.

Silica gel material passes through horn mouth 1 and gets into the machine, utilizes the mutual centre gripping of the gear of gear feeding mechanism A2 pay-off the inside to impel, sends silica gel to flying knife cutting structure 4 department, the accurate cutting silica gel length that sets up on human-computer interface 3 (this calculation mode is generally confirmed according to the rotational speed of the motor on gear feeding mechanism A2 and the diameter of pay-off gear, and this is prior art, and this application is not repeated), cuts in flying knife cutting structure 4 department. And after cutting, the cut rods enter a gear feeding mechanism B5 and are pushed forwards, finally the cut rods are sent out from a feeding nozzle 6 and stored on a material distribution wheel 8, a conveyor belt for the materials is arranged at the lower part of the material distribution wheel 8, and when the material distribution wheel 8 rotates to one side facing the conveyor belt, the rods fall onto the conveyor belt from a notch of the material distribution wheel by means of gravity, so that the rods are lined up and sent out.

Claims (5)

1. A numerical control silica gel precision cutting machine comprises a bell mouth (1), a gear feeding mechanism A (2), a fly cutter cutting structure (4), a gear feeding mechanism B (5), a feeding nozzle (6), a baffle plate (7), a material distributing wheel (8) and a conveyor belt (9), and is characterized in that the gear feeding mechanism A (2) and the gear feeding mechanism B (5) are installed on a workbench through bolts, the input and output ends of the gear feeding mechanism A (2) and the input and output ends of the gear feeding mechanism B (5) are coaxially arranged, wherein the input end of the gear feeding mechanism A (2) is connected with the bell mouth (1) through a feed pipeline, the fly cutter cutting structure (4) is installed between the output end of the gear feeding mechanism A (2) and the input end of the gear feeding mechanism B (5), the output end of the gear feeding mechanism B (5) is connected with one end of the feeding nozzle (6), and the other end of the feeding nozzle (6) faces the material distributing wheel (8); a rotating shaft of the distributing wheel (8) is rotatably installed on the racks on two sides of the conveying belt (9) through a bearing and a bearing seat, one end of the rotating shaft of the distributing wheel (8) is connected with a driving motor through a belt transmission mechanism, the driving motor can be fixedly connected to the bottom of the rack of the conveying belt (9), and the rotating direction of the distributing wheel (8) is opposite to the moving direction of the belt body of the conveying belt; a baffle (7) is arranged on one side of the material distribution wheel (8) with the rotating direction facing downwards, the baffle (7) is of an arc-surface structure corresponding to the surface of the material distribution wheel (8), and a silica gel rod can be accommodated between notches formed in the surfaces of the baffle (7) and the material distribution wheel (8) along the axial direction; the baffle (7) is fixedly connected to the racks on the two sides of the conveyor belt (9) through the support of the baffle.

2. The numerically controlled silica gel finishing machine according to claim 1, wherein the lower edge of the baffle (7) is tangent to the surface of the belt body of the conveyor belt.

3. The numerical control silica gel finishing machine according to claim 1, wherein the gear feeding mechanism a (2) and the gear feeding mechanism B (5) each include a housing and a set of feeding gears rotatably connected therein, a space for passing the silica gel rod is provided between a set of two feeding gears, and one ends of the two feeding gears, which are located at the outside, are connected to two transmission gears which are engaged with each other and engaged with a driving gear on an output end of a motor fixed on the surface of the housing.

4. The numerical control silica gel finishing machine according to claim 1, wherein the fly cutter cutting structure (4) also includes a corresponding driving motor and a corresponding cutting knife, the driving motor is fixedly connected to the worktable, and an output shaft of the driving motor is fixedly connected to one end of the cutting knife.

5. The numerical control silica gel smoothing mill of claim 1, characterized in that the uppermost of the distributing wheel (8) is provided with a pressing bar (10), two ends of the pressing bar (10) are respectively fixedly connected to the bearing seat and the feeding nozzle (6), and the pressing bar (10) ensures that the output glue stick is pressed in the surface notch of the distributing wheel (8).

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