KR100658598B1 - Gear Backlash Setting System of gearbox for Numerical Control Plastics Forming Machine - Google Patents

Abstract

The present invention relates to a gear clearance adjusting device for adjusting the gear clearance in order to transmit the driving force to the twin screw more precisely in the gearbox of the numerical control plastic molding machine. In the main shaft and the auxiliary shaft is connected to one side of the twin screw, the auxiliary shaft to rotate at the same speed as the main axis while maintaining the phase difference (90 degrees) with the main axis,

Mount the backlash gear that receives power from the main shaft to the side shaft, but form a port for injecting high pressure into the backlash gear, and form a flow path for inducing high pressure to the inner diameter of the backlash gear so that the backlash gear is expanded by applying heat. In order to adjust the gear clearance, the high pressure is injected into the port of the backlash gear to form a space between the backlash gear and the side shaft, and the backlash gear is rotated at a predetermined angle using the gap formed by the side shaft. The present invention relates to a gear gap adjusting device of a gear box for a numerically controlled plastic molding machine, which makes it easier to adjust a gear gap of a shaft.

Numerically controlled plastic molding machines, gear play, backlash, backlash

Description

Gear Backlash Setting System of Gearbox for Numerical Control Plastics Forming Machine}

1 is an exemplary view showing a numerically controlled plastic molding machine.

Figure 2 is a front view showing an extract of the gear clearance adjustment device of the conventional gearbox.

Figure 3 is a side view of the gear clearance adjustment device of Figure 2;

4 is a perspective view of the gear clearance adjustment device of FIG.

5 is an exploded perspective view showing an extract of the gear clearance adjustment device of FIG.

Figure 6 is a front view showing an extract of the gear clearance adjustment device of the gearbox according to the present invention.

Figure 7 is a side view of the gear clearance adjustment device of Figure 6;

FIG. 8 is a detailed view of portion B of FIG. 7;

9 to 12b is an exemplary view showing an assembly process and operation state of the gear clearance device according to the present invention.

Explanation of symbols on the main parts of the drawings

1: Numerical control plastic molding machine 2: Drive part

3: gearbox 4: twin screw extrusion

5: Raw material inlet 6: Twin screw

7: extruder die

10: gear clearance adjusting device 11: drive shaft

12: spindle 13: minor axis

14: side shaft 16: keyway

17: key 18: fixing bolt

19: bushing 20: flange

21: mounting hole 22: keyway

23: Backlash Gear 24: Tab

25, 27, 28: gear

30: Gear clearance adjusting device 31, 32: Side shaft

33, 34: Backlash Gear 35: Bore

36, 37: groove 38: euro

39: Euro 40: Closing bolt

41: port

The present invention relates to a gear clearance adjusting device for adjusting the gear clearance in order to transfer the driving force to the twin screw in a gearbox of a numerically controlled plastic molding machine at a more accurate timing.

More specifically, the driving force is received and decelerated at a predetermined speed to be transmitted to the main shaft, and the main shaft is connected to one side screw of the twin screw, and the outer side of the main shaft transmits power by the side shaft and a plurality of gears to the auxiliary shaft. Rotate the auxiliary shaft at the same speed as the main shaft while maintaining a phase difference (90 degrees) from the main shaft, and the auxiliary shaft is connected to the other screw of the twin screw.

Mount the backlash gear that receives power from the main shaft to the side shaft, but form a port for injecting high pressure into the backlash gear, and form a flow path for inducing high pressure to the inner diameter of the backlash gear so that the backlash gear is expanded by applying heat. In order to adjust the gear clearance, it is necessary to inject a high pressure into the port of the backlash gear so that the inner diameter of the backlash gear expands to form a space between the backlash gear and the side shaft, and to form the backlash gear by using the gap formed. The present invention relates to a gear gap adjusting device of a gear box for a numerically controlled plastic molding machine, which makes it easier to adjust the gear gap between the main shaft and the auxiliary shaft by rotating at an angle of.

In general, plastics are fed into a plastic molding machine, and the injected raw materials are melted by applying high temperature heat and extruded in one direction by twin screws, which are pulled out like an icicle while passing through the extruder die and cooled by a cooling means such as water The process then proceeds to the next step.

Typically, the numerically controlled plastic molding machine 1 has a drive unit 2 such as an electric motor on one side as shown in FIG. 1, and the driving force of the drive unit 2 is reduced at a predetermined speed and the main shaft 12. ) And a gearbox (3) for transmitting power to the auxiliary shaft (13), one side of the gearbox (3) constitutes a twin screw extrusion (4) by twin screw extrusion (4) In the plastic molding.

The twin screw extrusion part 4 forms a raw material inlet 5 at the upper end of the gearbox 3, and includes a heating means such as a heater, and is equipped with an extruder die 7 at the front end thereof in the longitudinal direction. A mandrel of a pair of long screw twin screw 6 is to connect the twin screw 6 to the main shaft 12 and the auxiliary shaft 13 of the gearbox 3, respectively.

The pair of twin screws 6 are formed in the same shape but are rotated in the same rotational direction by maintaining a phase difference of 90 degrees.

The present invention relates to a gear gap adjusting device for precisely adjusting the phase difference of the pair of twin screws (6) in the numerical control (NC) plastic molding machine among the plastic molding machine.

Conventional gear clearance adjustment device 10 is described with reference to FIGS. 2 to 5 as follows.

A mandrel is mounted on the driving shaft 11 receiving the power of the drive unit 2, and a mandrel is mounted on the main shaft 12 receiving the power by a reduction gear engaged with a helical gear. A twin screw 6 is connected to one of the pair of twin screws 6 (not specifically shown) to drive the twin screws 6, and the main shaft 12 has an electric gear 25 such as a helical gear. The backlash gear 23 is engaged with the gear 25, and the backlash gear 23 is fixed to the side shaft 14, and the side shaft 14 is mandrel mounted to the gearbox 3. will be.

Another gear 27 is formed at the front end of the side shaft 14, and the gear 27 is engaged with the gear 28 formed on the auxiliary shaft 13, and the auxiliary shaft 13 is a gear box 3. ) Is mounted in a mandrel, the auxiliary shaft 13 is mandrel mounted in equilibrium with the main shaft 12, and the tip of the auxiliary shaft 13 is connected to the other screw in the pair of twin screws (6). .

The backlash gear 23 is fixedly mounted to the side shaft 14 on one side, and the backlash gear 23 is rotated and fixed at a predetermined angle to adjust the gear clearance. Will be explained.

The bushing 19 is fitted to the side shaft 14 and fixed, and the backlash gear 23 is fitted to the bushing 19.

A key groove 16 is formed in the shaft portion of the side shaft 14.

The bushing 19 forms a flange 20 on one side, and a plurality of mounting holes 21 are formed in the flange 20 at equal intervals, but the mounting holes 21 are formed in an arc shape to form a predetermined angle. The inner diameter of the key groove 22 is formed.

The backlash gear 23 forms a tab 24 on one side thereof, but the position of the tab 24 is formed at a position corresponding to the mounting hole 21 of the bushing 19.

That is, the key 17 is inserted between the side shaft 14 and the bushing 19 so as to be fixed so as not to deviate from each other. The backlash gear 23 is inserted into the outer diameter of the bushing 19, and the flange 20 is mounted. The fixing bolt 18 is inserted into the ball 21 to fasten the fixing bolt 18 to the tab 24 of the backlash gear 23.

The conventional gear clearance adjusting device 10 configured as described above is operated as follows.

When the numerical control plastic molding machine 1 is started to drive, the plastic molding raw material in a solid state is introduced into the raw material inlet 5, and the injected raw material is heated by a heater to change its state like a semi-solid state.

On the other hand, the power of the drive unit 2 is transmitted to the pair of twin screws 6 by the gear box 3 to extrude the plastic raw material is changed as the semi-solid state, the plastic raw material is extruded die 7 While passing through it will be pulled out as long as a predetermined shape.

As shown in FIG. 2 and FIG. 3, the main shaft 12 receives the power of the driving shaft 11 to directly drive the twin screw 6 on one side, and the auxiliary shaft ( 13 is driven by the backlash gear 23 and the other gears 25 and 27 which mesh with the main shaft 12 to rotate the side shaft 14, and to match the gear 27 of the side shaft 14. The biting gear 28 drives the auxiliary shaft 13, and the auxiliary shaft 13 drives the other twin screw 6.

The pair of twin screws 6 only have to maintain a phase difference of 90 degrees to smoothly extrude the plastic material in the semi-solid state.

In order to adjust the phase difference of the pair of twin screws 6, a gear backlash is set in the gear box 3, in which the gear clearance adjusting device 10 is adjusted.

To adjust the gear clearance, first loosen the backlash gear 23 fixed to one side shaft 14, adjust the gear clearance, and then loosen the fixing bolt 18 by tightening again, and the backlash gear 23 from the bushing 19. ) Is to tighten the fixing bolt 18 finely rotated at a predetermined angle, the rotatable range of the backlash gear 23 is limited to the size of the mounting hole (21).

However, the above conventional gear clearance adjusting device 10 is pointed out the following problems.

In order to adjust the gear clearance, all the fixing bolts 18 fastened to the bushing 19 and the backlash gear 23 must be loosened and tightened, which is very cumbersome, takes a long time to adjust the gear clearance, and the range in which the gear clearance can be adjusted is To be limited to the size of the mounting hole 21, there was a problem that the gear clearance must be adjusted within a very limited range.

In addition, a separate part, such as a bushing 19, must be additionally mounted, and occupies a space for fixing the fixing bolt 18 and a space formed by the flange 20, and the inside of the limited gearbox 3 is limited. In order to mount, it is necessary to narrowly design the tooth width of the other gear 25 and the gear 26 meshing with the backlash gear 23, and by designing such a narrow tooth width, the contact surface of the gear is reduced.

However, the twin screw extruder (4) requires a larger torque, the narrower the contact surface of the gear can not transmit more torque, and there is a problem that the torque that can be transmitted is very limited.

The present invention is to provide a gear gap adjusting device of a gear box for a numerically controlled plastic molding machine to solve the above problems.

The present invention provides a gearbox for a numerically controlled plastic molding machine that is equipped with a backlash gear on both side shafts engaged with the main shaft to expand the gear clearance adjustment range so that the phase of the pair of twin screws can be more precisely adjusted. The purpose is to provide a clearance adjustment.

Another object of the present invention is to fasten the backlash gear to the side shaft so as to form the width of the backlash gear and the gear as wide as possible to secure the space to be secured by eliminating the additional parts such as bushing, without fastening the fixing bolt as conventionally Therefore, the present invention provides a gear gap adjusting device of a gear box for a numerically controlled plastic molding machine that can transmit maximum torque even in a limited space within a gear box.

Still another object of the present invention is to form a flow path so that the hydraulic pressure can flow to the inner diameter of the backlash gear in mounting the backlash gear on the side shaft, and on one side of the backlash gear to form a port for receiving a high pressure hydraulic pressure, heat to the backlash gear In the expanded state, insert into the side axle and cool down to fix it.To adjust the gear clearance of the backlash gear, supply a high pressure hydraulic pressure to the backlash gear so that a space is formed between the inner diameter of the backlash gear and the side axle. In this state, the backlash gear is rotated in the desired direction to adjust the play of the gear. Any position can be arbitrarily adjusted in the 360 degree range, and the high pressure hydraulic pressure is injected or released once between the backlash gear and the side shaft. Numerically controlled plastics enable faster setting and release of detention Type to provide the gear clearance adjustment apparatus of the appointed gearbox.

The above objects and features of the present invention will be more clearly understood by the following detailed description based on the accompanying drawings.

Figure 6 is a front view showing the gear clearance adjustment device of the gearbox according to the present invention, Figure 7 is a side view of the gear clearance adjustment device of Figure 6, Figure 8 is a detailed view of the portion B of Figure 7, 9 to 12b are exemplary views showing an assembly process and an operation example of the gear clearance device according to the present invention.

Gear gap adjustment device 30 according to the present invention, as shown in the accompanying drawings, Figures 6 to 9, a pair of side shafts receiving power from the main shaft 12 to transfer power to the auxiliary shaft 13 ( 31 and 32 are equipped with backlash gears 33 and 34. The same components as those of the conventional gear clearance adjusting device 10 are denoted by the same reference numerals and detailed description thereof will be omitted.

As shown in FIG. 6, the gear clearance adjusting device 30 according to the present invention includes a pair of backlash gears 33 and 34 to be engaged with the gear 25 of the main shaft 12. ), The mounting process and the specific embodiment will be described with reference to FIGS. 9 to 11B.

The backlash gears 33 and 34 form a plurality of grooves 36 in the inner diameter 35, form a flow path 39 in the horizontal direction, and fasten the closing bolt 40 to an end of the flow path 39. As a result, the end of the flow path 39 was closed, and a flow path 38 connecting the groove 36 and the flow path 39 was formed, and the backlash gears 33 and 34 are formed at the inner end of the flow path 39. A port 41 communicating with the outer diameter side of the was formed.

The port 41 can be supplied with a high pressure hydraulic pressure.

The shaft portion 31a of the side shafts 31 and 32 is formed into a cylindrical shape without any additional key grooves.

When the backlash gears 33 and 34 are inserted into and mounted on the side shafts 31 and 32, as shown in FIG. 10, the backlash gears 33 and 34 are heated to thermally expand and expand to expand the inner diameter ( When the side shafts 31 and 32 are inserted in the extended state, the shaft portion 31a is fitted as shown in FIG. 11A. When the heat is cooled, the backlash gears 33 and 34 contract and the inner diameter is reduced. 35 is in close contact with the shaft portion 31a to be firm and fixed.

1 and 6 to 12b will be described the operation state of the gear clearance adjusting device 30 according to the present invention.

When adjusting the gear clearance, as shown in FIG. 12B, a high pressure hydraulic pressure is connected to the port 41, and high pressure is injected.

When the high pressure hydraulic pressure is injected into the port 41, the hydraulic pressure moves along the flow paths 39 and 38 to reach the grooves 36 and 37. When the hydraulic pressure is continuously applied, the inner diameter 35 and the shaft portion 31a are applied. The middle portion of the inner diameter 35 is expanded in between to form a predetermined interval.

In particular, the expansion is formed is the hydraulic pressure is applied along the grooves 36, 37 formed in the inner diameter is to inflate like a tube without biasing to either side.

As described above, the backlash gears 33 and 34 are moved in any direction in a state where a space is formed between the inner diameter 35 of the backlash gears 33 and 34 and the shaft portions 31a of the side shafts 31 and 32. Rotate to adjust gear clearance.

If the backlash gears 33 and 34 are rotated to an arbitrary position to adjust the gear clearance and then the high pressure is removed, the backlash gears 33 and 34 contract to their original state and are firmly attached to the side shafts 31 and 32. It is fixed.

Therefore, by injecting a high pressure in a single position as described above to form a space between the backlash gears 33, 34 and the side shafts 31, 32, the gears by rotating the backlash gears 33, 34 more quickly. The play can be adjusted.

In addition, the backlash gears 33 and 34 can be adjusted on both side shafts 31 and 32 so that the backlash gears 33 and 34 can be fixed in a more precise position.

Although specific embodiments have been described in the present invention, it will be apparent to those skilled in the art that various changes and modifications can be made within the technical scope of the present invention, and such modifications and modifications belong to the appended claims.

Therefore, the gear clearance adjusting device 30 of the gearbox for the numerically controlled plastic molding machine according to the present invention does not require an additional component such as a separate bushing 19 as in the conventional example, and thus takes up the space occupied by the bushing 19. The width of the backlash gears 33 and 34 and the main shaft 12 of the backlash gears 33 and 34 can be secured by eliminating the fixing bolt 18 to which the bushing 19 and the backlash gear are fixed. It is possible to design a wide width of the gear 25 of the gear, so that the wider engagement range of the gear can be transmitted to a greater torque.

In addition, in adjusting the gear clearance, by injecting a high pressure hydraulic pressure into the backlash gear, the detention force of the backlash gears 33, 34 and the side shafts 31, 32 can be released more quickly. Simultaneously with the removal of the hydraulic pressure, the detention force of the backlash gears 33 and 34 and the side shafts 31 and 32 can be set more quickly, thereby significantly reducing the time due to the gear clearance adjustment.

In addition, by mounting the backlash gear 33 and the backlash gear 34 to both the pair of side shaft 31 and the side shaft 32 to be engaged with the main shaft 12, the gear clearance adjustment range can be further expanded. The more precise gear clearance adjustment is possible, so that the pair of twin screws 6 can be driven while maintaining a precise phase difference.

Claims (1)

In the gearbox 3, a mandrel of the main shaft 12 receiving the power of the driving shaft 11 is mounted on the mandrel, and a tip of the main shaft 12 is attached to any one of the pair of twin screws 6. By connecting to drive the twin screw (6), the main shaft (12) forms an electric gear (25), the other end (27) to the front end of the side shaft 14, the mandrel mounted on the gear box (3) And an auxiliary shaft 13 which is engaged with the gear 27 of the side shaft 14 to receive power and is mounted on a mandrel to the gearbox 3, and a pair of twin screws 6 are provided at the tip of the auxiliary shaft 13. Connecting the other twin screw 6 to drive the twin screw 6; Gear 25 of the main shaft 12 is engaged with the backlash gear 33 and the backlash gear 34 respectively mounted on the other auxiliary shafts 31 and 32; The backlash gears 33 and 34 form a plurality of grooves 36 and 37 in the inner diameter 35, form a flow path 39 in a horizontal direction, and a closing bolt (at the end of the flow path 39). 40 is fastened to close the end of the flow path 39, and a flow path 38 connecting the grooves 36 and 37 and the flow path 39 is formed, and a backlash gear is formed at an inner end of the flow path 39. (33) (34) is formed so as to communicate with the port 41 toward the outer diameter so as to supply a high pressure hydraulic pressure to the port 41; gear gap adjusting device for a gear box for a numerically controlled plastic molding machine, characterized in that.

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