CN216632870U - Servo transmission mechanism of numerical control gear shaping machine - Google Patents

Abstract

The utility model discloses a servo transmission mechanism of a numerical control gear shaping machine, belonging to the technical field of industrial production, wherein a connecting groove is arranged at the middle part of the top of a limiting groove, driving components are arranged at two sides in a limiting frame, a belt pulley component is arranged on the driving components, a belt component is arranged on the belt pulley component, a transmission component is arranged on the driving components, a connecting gear shaping component is arranged at the bottom of the transmission component, a worker positions and connects the gear shaping machine through a connecting rod and a connecting plate, after connection is finished, when the gear shaping machine needs to move in use, the first driving motor and the second driving motor are started to drive a second rotating rod, a driven rotating rod, a first rotating rod, a second belt pulley, a first belt pulley, a third belt pulley, a fourth belt pulley, a first belt, a second belt and a gear to rotate, and a rack is driven to slide and move in the limiting groove, the sliding groove and the connecting groove through the rotation of the gear, thereby reach the operation simpler, promote the effect better, be convenient for remove.

Description

Servo transmission mechanism of numerical control gear shaping machine

Technical Field

The utility model relates to a servo transmission mechanism, in particular to a servo transmission mechanism of a numerical control gear shaper, and belongs to the technical field of industrial production.

Background

The bevel gear has the characteristics of smooth transmission and low vibration and noise in the meshing process, is widely used in high-speed, heavy-load and low-noise transmission, and the gear shaping is an irreplaceable gear machining method with a plurality of advantages.

Gear shaping is a common method for machining helical gears, and in addition to generating motion between a cutter shaft and a workpiece during machining, in order to realize machining of helical teeth, the cutter shaft of the gear shaping also needs additional rotary motion, and the direction of the rotary motion is changed frequently in the forward direction and the reverse direction.

The existing gear shaping machine transmission mechanism is complex in operation and poor in pushing effect, so that a numerical control gear shaping machine servo transmission mechanism is urgently needed to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide a numerical control gear shaping machine servo transmission mechanism, wherein a worker positions and connects a gear shaping machine through a connecting rod and a connecting plate, after connection is good, when the gear shaping machine needs to move in use, the worker starts a first driving motor and a second driving motor to drive a second rotating rod, a driven rotating rod, a first rotating rod, a second belt pulley, a first belt pulley, a third belt pulley, a fourth belt pulley, a first belt, a second belt and a gear to rotate, and a rack is driven to slide and move in a limiting groove, a sliding groove and a connecting groove through rotation of the gear, so that the purposes of simpler operation, better pushing effect and convenience for moving are achieved.

The purpose of the utility model can be achieved by adopting the following technical scheme:

the utility model provides a numerical control gear shaping machine servo drive mechanism, includes spacing, spacing groove, sliding tray and spread groove, and spacing groove is installed to spacing interior middle part hypomere department, and the sliding tray is seted up in spacing tank bottom middle part department, and the spread groove is seted up in spacing groove top middle part department, and drive assembly is installed to spacing inside both sides, is equipped with the pulley subassembly on the drive assembly, is equipped with the belt subassembly on the pulley subassembly, is equipped with drive assembly on the drive assembly, and the connection gear shaping subassembly is installed to the drive assembly bottom.

Preferably, the drive assembly comprises a first drive motor, a second rotating rod, a driven rotating rod and a first rotating rod, the first drive motor is arranged at one side of the middle part of the limiting frame, the second drive motor is arranged at one side of the first drive motor, the second rotating rod is arranged at the output end of the second drive motor, the first rotating rod is arranged at the output end of the first drive motor, and the driven rotating rod is arranged at the lower section of the limiting frame.

Preferably, the belt pulley assembly comprises a second belt pulley, a first belt pulley, a third belt pulley and a fourth belt pulley, the second belt pulley is sleeved at two sides of the middle of the second rotating rod, the third belt pulley is sleeved at two sides of the middle of the rotating rod, the first belt pulley is sleeved at two sides of the middle of the first rotating rod, and the fourth belt pulley is sleeved at one side of the third belt pulley.

Preferably, the belt assembly comprises a first belt and a second belt, the first belt is sleeved between the first belt pulley and the third belt pulley, and the second belt is sleeved between the second belt pulley and the fourth belt pulley.

Preferably, the transmission assembly comprises a rack and a gear, the gear is sleeved in the middle of the driven rotating rod, and the rack is inserted into the middle of the limiting groove and is in sliding connection.

Preferably, the connecting and gear shaping assembly comprises a connecting rod, a connecting plate and a gear shaping machine, the connecting rod is installed at the middle part of the bottom of the rack, the connecting plate is installed at the bottom of the connecting rod, and the gear shaping machine is installed at the bottom of the connecting rod.

The utility model has the beneficial technical effects that:

according to the numerical control gear shaping machine servo transmission mechanism provided by the utility model, a worker positions and connects the gear shaping machine through the connecting rod and the connecting plate, after connection is still good, when the gear shaping machine needs to move in use, the first driving motor and the second driving motor are started to drive the second rotating rod, the driven rotating rod, the first rotating rod, the second belt pulley, the first belt pulley, the third belt pulley, the fourth belt pulley, the first belt, the second belt and the gear to rotate, and the gear rotates to drive the rack to slide and move in the limiting groove, the sliding groove and the connecting groove, so that the purposes of simpler operation, better pushing effect and convenience for moving are achieved.

Drawings

FIG. 1 is a front elevational view of the overall construction of a preferred embodiment of a servo drive mechanism for a numerically controlled gear shaper in accordance with the present invention;

FIG. 2 is a side elevational view of the overall construction of a preferred embodiment of a servo drive mechanism of a numerically controlled gear shaper in accordance with the present invention;

fig. 3 is a schematic view of a sliding connection structure of a preferred embodiment of a servo transmission mechanism of a numerical control gear shaper according to the utility model.

In the figure: 1-a limiting frame, 2-a first driving motor, 3-a second driving motor, 4-a second rotating rod, 5-a second belt pulley, 6-a driven rotating rod, 7-a first belt pulley, 8-a first rotating rod, 9-a first belt, 10-a second belt, 11-a third belt pulley, 12-a limiting groove, 13-a sliding groove, 14-a rack, 15-a gear, 16-a connecting groove, 17-a connecting rod, 18-a connecting plate, 19-a gear shaping machine and 20-a fourth belt pulley.

Detailed Description

In order to make the technical solutions of the present invention more clear and definite for those skilled in the art, the present invention is further described in detail below with reference to the examples and the accompanying drawings, but the embodiments of the present invention are not limited thereto.

As shown in fig. 1-3, the servo transmission mechanism of the numerical control gear shaping machine provided by the present embodiment includes a limiting frame 1, a limiting groove 12, a sliding groove 13 and a connecting groove 16, the limiting groove 12 is installed at the lower section of the middle part in the limiting frame 1, the sliding groove 13 is opened at the middle part of the bottom of the limiting groove 12, the connecting groove 16 is opened at the middle part of the top of the limiting groove 12, driving components are installed at two sides of the inside of the limiting frame 1, a belt pulley component is installed on the driving components, a belt component is installed on the belt pulley component, a transmission component is installed on the driving components, and a connecting gear shaping component is installed at the bottom of the transmission component.

The general working principle is as follows: the staff carries out the location connection with gear shaping machine 19 through including connecting rod 17 and connecting plate 18, connect and still after good when the use need remove through starting first driving motor 2 and second driving motor 3 drive second dwang 4, from dwang 6, first dwang 8, second belt pulley 5, first belt pulley 7, third belt pulley 11, fourth belt pulley 20, first belt 9, second belt 10 and gear 15 rotate, drive rack 14 in spacing groove 12 through the rotation of gear 15, slide groove 13 and spread groove 16 slide and remove, thereby reach the operation simpler, it is better to promote the effect, be convenient for remove.

In this embodiment: the drive assembly comprises a first drive motor 2, a second drive motor 3, a second rotating rod 4, a driven rotating rod 6 and a first rotating rod 8, the first drive motor 2 is installed at one side of the middle part of the limiting frame 1, the second drive motor 3 is installed at one side of the first drive motor 2, the second rotating rod 4 is installed at the output end of the second drive motor 3, the first rotating rod 8 is installed at the output end of the first drive motor 2, and the driven rotating rod 6 is installed at the middle lower section of the limiting frame 1.

The local working principle is as follows: driven by the first drive motor 2, the second drive motor 3, the second rotating lever 4, the driven rotating lever 6, and the first rotating lever 8.

In this embodiment: the belt pulley assembly comprises a second belt pulley 5, a first belt pulley 7, a third belt pulley 11 and a fourth belt pulley 20, the second belt pulley 5 is sleeved on two sides of the middle of the second rotating rod 4, the third belt pulley 11 is sleeved on two sides of the middle of the driven rotating rod 6, the first belt pulley 7 is sleeved on two sides of the middle of the first rotating rod 8, and the fourth belt pulley 20 is sleeved on one side of the third belt pulley 11.

The local working principle is as follows: is rotated by the second pulley 5, the first pulley 7, the third pulley 11 and the fourth pulley 20.

In this embodiment: the belt assembly comprises a first belt 9 and a second belt 10, the first belt 9 is sleeved between the first belt pulley 7 and the third belt pulley 11, and the second belt 10 is sleeved between the second belt pulley 5 and the fourth belt pulley 20.

The local working principle is as follows: the connection is made by a first belt 9 and a second belt 10.

In this embodiment: the transmission assembly comprises a rack 14 and a gear 15, the gear 15 is sleeved in the middle of the driven rotating rod 6, and the rack 14 is inserted into the middle of the limiting groove 12 and is in sliding connection.

The local working principle is as follows: the rack 14 and the gear 15 are meshed with each other and are in transmission connection.

In this embodiment: the connecting gear shaping assembly comprises a connecting rod 17, a connecting plate 18 and a gear shaping machine 19, wherein the connecting rod 17 is installed at the middle of the bottom of the rack 14, the connecting plate 18 is installed at the bottom of the connecting rod 17, and the gear shaping machine 19 is installed at the bottom of the connecting rod 17.

The local working principle is as follows: the connection is made by a connecting rod 17, a connecting plate 18 and a gear shaper 19.

The above description is only for the purpose of illustrating the present invention and is not intended to limit the scope of the present invention, and any person skilled in the art can substitute or change the technical solution of the present invention and its conception within the scope of the present invention.

Claims (6)

1. The utility model provides a numerical control gear shaping machine servo drive mechanism which characterized in that: including spacing (1), spacing groove (12), sliding tray (13) and spread groove (16), spacing groove (12) are installed to middle part hypomere department in spacing (1), sliding tray (13) are seted up at spacing groove (12) end middle part department, spacing groove (12) top middle part department is seted up in spread groove (16), drive assembly is installed to spacing (1) inside both sides, the last belt pulley subassembly that is equipped with of drive assembly, the last belt assembly that is equipped with of belt pulley subassembly, the last drive assembly that is equipped with of drive assembly, the connection gear shaping subassembly is installed to the drive assembly bottom.

2. The servo transmission mechanism of a numerical control gear shaping machine according to claim 1, characterized in that: the driving assembly comprises a first driving motor (2), a second driving motor (3), a second rotating rod (4), a driven rod (6) and a first rotating rod (8), the first driving motor (2) is installed at one side of the middle of the limiting frame (1), the second driving motor (3) is installed at one side of the first driving motor (2), the second rotating rod (4) is installed at the output end of the second driving motor (3), the first rotating rod (8) is installed at the output end of the first driving motor (2), and the driven rod (6) is installed at the middle lower section of the limiting frame (1).

3. The servo transmission mechanism of a numerical control gear shaping machine according to claim 2, characterized in that: the belt pulley component comprises a second belt pulley (5), a first belt pulley (7), a third belt pulley (11) and a fourth belt pulley (20), the second belt pulley (5) is sleeved on two sides of the middle of the second rotating rod (4), the third belt pulley (11) is sleeved on two sides of the middle of the driven rotating rod (6), the first belt pulley (7) is sleeved on two sides of the middle of the first rotating rod (8), and the fourth belt pulley (20) is sleeved on one side of the third belt pulley (11).

4. The servo transmission mechanism of a numerical control gear shaping machine according to claim 3, characterized in that: the belt component comprises a first belt (9) and a second belt (10), the first belt (9) is sleeved between the first belt pulley (7) and the third belt pulley (11), and the second belt (10) is sleeved between the second belt pulley (5) and the fourth belt pulley (20).

5. The servo transmission mechanism of a numerical control gear shaping machine according to claim 4, characterized in that: the transmission assembly comprises a rack (14) and a gear (15), the gear (15) is sleeved in the middle of the driven rod (6), and the rack (14) is inserted into the middle of the limiting groove (12) and is in sliding connection.

6. The servo transmission mechanism of a numerical control gear shaping machine according to claim 5, characterized in that: the connecting gear shaping assembly comprises a connecting rod (17), a connecting plate (18) and a gear shaping machine (19), the connecting rod (17) is installed at the middle part of the bottom of the rack (14), the connecting plate (18) is installed at the bottom of the connecting rod (17), and the gear shaping machine (19) is installed at the bottom of the connecting rod (17).

Images