CN220596231U - Auxiliary automatic feeding device for wooden door cutting - Google Patents

Abstract

The utility model discloses an auxiliary automatic feeding device for wooden door cutting, which comprises a cabinet, wherein a lifting mechanism is arranged in the cabinet and is connected with a lifting table; the left and right sides of rack are equipped with cuts frame and pushing equipment, are equipped with preceding, back conveying mechanism on the elevating platform, cut frame and pushing equipment and be equipped with horizontal push hole on being located back conveying mechanism's both sides and cutting the frame, and pushing equipment's output is from a left side to right in pushing the door plant of elevating platform rear side into the push hole through installing the guillootine on cutting the frame to the door plant cut. In the method, the wood boards are stacked on the lifting table, lifted by the lifting mechanism and pushed to the cutting frame through the pushing mechanism to be cut through the cutting machine, and when the door plate on the top layer is pushed away and cut, the lifting table continuously lifts the height of one door plate thickness and pushes and cuts until all the door plates are cut; compared with a feeding structure sucked by a manipulator, the device has the advantages of small occupied area, low cost and high efficiency.

Description

Auxiliary automatic feeding device for wooden door cutting

Technical Field

The utility model relates to wood door manufacturing equipment, in particular to an auxiliary automatic feeding device for wood door cutting.

Background

The timber is extensively applicable to people, commercial building and house, and the timber need cut it through the guillootine in the course of working to reach required size.

At present, all adopt conveyer and manipulator's equipment to go on at used feed mechanism of timber when cutting, absorb the door plant through sucking disc on the manipulator when snatching, then place on the conveyer and carry to the guillootine department through the conveyer, then fix and cut.

In the prior art, when a door plate is fed by adopting a manipulator, the manipulator is required to complete two actions of sucking and conveying, and the manipulator is required to be a multi-axis manipulator and is required to be provided with a sucking disc and an air source station, so that the cost is greatly increased; in addition, the action range of the mechanical arm in the sucking and conveying process is large, and additionally, the door plate stacking place is required to be additionally arranged, so that the whole feeding equipment occupies too large production area, and the cost is further increased; finally, the gesture of the door plate can not be obtained when the manipulator sucks the door plate, so that the stacking gesture and the position of the door plate are also high in requirements.

Disclosure of Invention

Based on the defects of large occupied area, complex equipment and high cost of the prior art that a manipulator with a sucker is used for feeding the door plate, the utility model provides an auxiliary automatic feeding device for cutting a wooden door.

The technical scheme adopted for solving the technical problems is as follows:

the auxiliary automatic feeding device for wood door cutting comprises a cabinet, wherein a lifting mechanism is arranged in the cabinet, an opening is formed in the front side of the cabinet, a lifting table is arranged at the opening of the cabinet, and the lifting table is driven by the lifting mechanism to lift; the left and right sides of the cabinet are respectively provided with a cutting frame for installing a cutting machine and a pushing mechanism for pushing the door plate, the front and rear sides of the lifting platform are respectively provided with a front conveying mechanism and a rear conveying mechanism, the cutting frame and the pushing mechanism are positioned on the two sides of the rear conveying mechanism and are provided with horizontal pushing holes, and the output end of the pushing mechanism pushes the door plate on the rear side of the lifting platform from left to right into the pushing holes to cut the door plate through the cutting machine installed on the cutting frame. According to the technical scheme, the boards are stacked on the lifting table, lifted by the lifting mechanism and pushed to the cutting frame through the pushing mechanism, and cut through the cutting machine, and in the lifting process of the lifting table, after the door plate on the top layer is pushed away and cut, the lifting table continuously lifts the height of one door plate until all the door plates are cut; wherein, a group of door plates are respectively arranged at the front conveying mechanism and the rear conveying mechanism, and the door plates at the front conveying mechanism can be conveyed to the rear conveying mechanism after the door plates at the rear conveying mechanism are cut.

Preferably, the lifting mechanism is a screw lifter, a driving part of the screw lifter is a driving motor, and the driving motor is controlled by a control mechanism.

Preferably, the control mechanism comprises an angle sensor and a PLC controller, the angle sensor is meshed with an output shaft of the driving motor through a group of gears to read the rotation angle, the angle sensor is connected with the PLC controller to feed back the read angle information to the PLC controller, and the PLC controller is connected with the driving motor to control the driving motor to operate. According to the scheme, the rotation angle of the driving motor is read through the angle sensor and is fed back to the PLC, and the lifting height of the lifting mechanism is indirectly controlled by controlling the driving motor through the PLC.

Preferably, the control mechanism comprises a groove-shaped optical coupler sensor and a PLC controller, wherein the groove-shaped optical coupler sensor comprises a groove-shaped optical coupler arranged on the cabinet and a shielding piece arranged on the lifting part of the screw lifter, and the shielding piece can extend into a position between a light emitting end and a receiving end of the groove-shaped optical coupler to shield light; the groove-type optical coupler sensor and the driving motor are connected with the PLC, the groove-type optical coupler sensor is used for feeding back the height position of the lifting part of the screw lifter to the PLC, and the PLC controls the driving motor to operate. According to the scheme, the lifting height is read through the groove-type optocoupler sensor and fed back to the PLC, and the PLC is used for controlling the driving motor to directly control the lifting height of the lifting mechanism.

Preferably, the groove-shaped optocouplers are arranged at equal intervals, and the groove-shaped optocouplers are powered in a scanning mode. Only one groove-shaped optocoupler is electrified at the same time when scanning power supply is performed, so that electric energy can be greatly saved.

Preferably, the front conveying mechanism and the rear conveying mechanism comprise a shared frame, a front conveyor and a rear conveyor which are arranged in the shared frame, the front conveyor and the rear conveyor comprise conveying motors, conveying rollers and conveying belts, and the conveying belts are sleeved on the conveying rollers and driven by the conveying motors. Specifically, the conveying motors are arranged in two groups and are respectively responsible for driving the two groups of conveying belts.

Preferably, the conveyor belts of the front conveyor and the rear conveyor are alternately arranged left and right, and the conveyor belts of the front conveyor and the rear conveyor have overlapping portions in the front-rear direction. During the conveying process, the two conveyors cooperate to convey the door panels to the desired rear side.

Preferably, the cutting frame is provided with a strip-shaped cutting opening, and the output end of the cutting machine extends into the cutting opening to cut the door plate below.

Preferably, the cabinet comprises a rear cabinet body and a front cabinet body, the lifting mechanism is arranged in the rear cabinet body, two upright posts are respectively arranged on two sides of the front end of the front cabinet body, a connecting crosspiece is arranged on the lower sides of the two upright posts, and the lifting platform extends into the front cabinet body from the front side of the connecting crosspiece through the upper part of the connecting crosspiece and extends into the rear cabinet body to be connected with the output end of the lifting mechanism. In this scheme, the stand can carry out spacingly to the door plant.

Preferably, a front vertical plate is arranged below the connecting crosspiece, and a left vertical plate and a right vertical plate are respectively arranged between the upright posts on the left side and the right side and the rear cabinet body; the bottoms of the front cabinet body and the rear cabinet body are provided with a bottom plate. In this scheme, each riser is to enclosing the cabinet body, improves the security.

Specifically, the pushing mechanism is a pushing motor or a pushing cylinder, and the output end of the pushing mechanism is provided with a pushing plate.

Compared with the prior art, the utility model has the advantages that: in the application, stacking the wood boards on the lifting table, lifting the wood boards by the lifting mechanism, pushing the wood boards to the cutting frame through the pushing mechanism, and cutting the wood boards by the cutting machine, wherein in the lifting process of the lifting table, when the door plate on the top layer is pushed away and cut, the lifting table continuously lifts the height of one door plate thickness and pushes the wood boards to cut until all the door plates are cut; the front conveying mechanism and the rear conveying mechanism are respectively provided with a group of door plates, and the door plates at the front conveying mechanism can be conveyed to the rear conveying mechanism after the door plates at the rear conveying mechanism are cut; compared with a feeding structure sucked by a manipulator, the device has the advantages of small occupied area, low cost and high efficiency.

Drawings

The utility model will be described in further detail below in connection with the drawings and the preferred embodiments, but it will be appreciated by those skilled in the art that these drawings are drawn for the purpose of illustrating the preferred embodiments only and thus should not be taken as limiting the scope of the utility model. Moreover, unless specifically indicated otherwise, the drawings are merely schematic representations, not necessarily to scale, of the compositions or constructions of the described objects and may include exaggerated representations.

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a top view of the present utility model;

FIG. 3 is a rear view of the present utility model;

FIG. 4 is a rear view of the utility model (with the cabinet rear panel removed);

in the figure: 10. a cabinet; 101. a rear cabinet body; 102. a front cabinet body; 1021. a column; 1022. a connecting crosspiece; 20. a lifting table; 201. a front conveying mechanism; 202. a rear conveying mechanism; 30. a lifting mechanism; 301. a driving motor; 40. a cutting frame; 401. pushing the hole; 50. and the pushing mechanism.

Detailed Description

The preferred embodiments of the present utility model will be described in detail below with reference to the drawings, and those skilled in the art will appreciate that the descriptions are merely illustrative, exemplary, and should not be construed as limiting the scope of the present utility model.

It should be noted that: like reference numerals denote like items in the following figures, and thus once an item is defined in one figure, it may not be further defined and explained in the following figures.

Examples

The title of the auxiliary automatic feeding device for wood door cutting is mainly described in the embodiment, and the title is specifically as follows:

the auxiliary automatic feeding device for wood door cutting comprises a cabinet 10, wherein a lifting mechanism 30 is arranged in the cabinet 10, an opening is formed in the front side of the cabinet 10, a lifting table 20 is arranged at the opening of the cabinet 10, and the lifting table 20 is driven to lift by the lifting mechanism 30; the left and right sides of the cabinet 10 are respectively provided with a cutting frame 40 for installing a cutting machine and a pushing mechanism 50 for pushing a door plate, the front and rear sides of the lifting table 20 are respectively provided with a front conveying mechanism 201 and a rear conveying mechanism 202, the cutting frame 40 and the pushing mechanism 50 are positioned on two sides of the rear conveying mechanism 202, the cutting frame 40 is provided with a horizontal pushing hole 401, and the output end of the pushing mechanism 50 pushes the door plate on the rear side of the lifting table 20 into the pushing hole 401 from left to right, and the door plate is cut by the cutting machine installed on the cutting frame 40. In the scheme, the wood boards are stacked on the lifting table 20 and lifted by the lifting mechanism 30 and then pushed to the cutting frame 40 by the pushing mechanism 50 to be cut by a cutting machine, and in the lifting process of the lifting table 20, when the top door plate is pushed away and cut, the lifting table 20 continuously lifts the height of one door plate thickness until all the door plates are cut; wherein, a group of door panels are respectively arranged at the front conveying mechanism 202 and the rear conveying mechanism 202, and the door panels at the front conveying mechanism 201 can be conveyed to the rear conveying mechanism 202 after the door panels at the rear conveying mechanism 202 are cut. It should be noted that, the top of the cutting frame 40 may be provided with an open structure to facilitate installation of the cutting mechanism.

Preferably, the lifting mechanism 30 is a screw lifter, the driving part of the screw lifter is a driving motor 301, and the driving motor 301 is controlled by a control mechanism.

Preferably, the control mechanism includes an angle sensor and a PLC controller, the angle sensor is engaged with an output shaft of the driving motor 301 through a set of gears to read a rotation angle, and the angle sensor is connected with the PLC controller to feed back the read angle information to the PLC controller, and the PLC controller is connected with the driving motor 301 to control the operation of the driving motor 301. The rotation angle of the driving motor 301 is read through the angle sensor, and is fed back to the PLC controller, and the lifting height of the lifting mechanism 30 is indirectly controlled by controlling the driving motor 301 through the PLC controller.

Preferably, the control mechanism comprises a groove-shaped optical coupler sensor and a PLC controller, wherein the groove-shaped optical coupler sensor comprises a groove-shaped optical coupler arranged on the cabinet 10 and a shielding piece arranged on the lifting part of the screw lifter, and the shielding piece can extend into a position between a light emitting end and a receiving end of the groove-shaped optical coupler to shield light; the groove-type optocoupler sensor and the driving motor 301 are connected with the PLC, the groove-type optocoupler sensor is used for feeding back the height position of the lifting part of the screw lifter to the PLC, and the PLC controls the driving motor 301 to operate. The lifting height is read through the groove-type optocoupler sensor, and is fed back to the PLC controller, and the lifting height of the lifting mechanism 30 is directly controlled by controlling the driving motor 301 through the PLC controller.

Preferably, the groove-shaped optocouplers are arranged at equal intervals, and the groove-shaped optocouplers are powered in a scanning mode. Only one groove-shaped optocoupler is electrified at the same time when scanning power supply is performed, so that electric energy can be greatly saved.

Preferably, the front conveying mechanism 201 and the rear conveying mechanism 202 comprise a common frame and a front conveyor and a rear conveyor arranged in the common frame, wherein the front conveyor and the rear conveyor comprise a conveying motor, conveying rollers and a conveying belt, and the conveying belt is sleeved on the conveying rollers and driven by the conveying motor. Specifically, the conveying motors are arranged in two groups and are respectively responsible for driving the two groups of conveying belts.

Preferably, the conveyor belts of the front conveyor and the rear conveyor are alternately arranged left and right, and the conveyor belts of the front conveyor and the rear conveyor have overlapping portions in the front-rear direction. During the conveying process, the two conveyors cooperate to convey the door panels to the desired rear side.

Preferably, the cutting frame 40 is provided with a strip-shaped cutting opening, and the output end of the cutting machine extends into the cutting opening to cut the door panel below.

Preferably, the cabinet 10 includes a rear cabinet body 101 and a front cabinet body 102, the lifting mechanism 30 is disposed in the rear cabinet body 101, two sides of the front end of the front cabinet body 102 are respectively provided with a column 1021, the lower sides of the two columns 1021 are provided with a connecting crosspiece 1022, and the lifting platform 20 passes through the upper part of the connecting crosspiece 1022 from the front side of the connecting crosspiece 1022 and extends into the front cabinet body 102 and into the rear cabinet body 101 to be connected with the output end of the lifting mechanism 30. In this scheme, the stand 1021 can limit the door panel.

Preferably, a front vertical plate is arranged below the connecting crosspiece 1022, and a left vertical plate and a right vertical plate are respectively arranged between the upright 1021 on the left side and the right side and the rear cabinet body 101; a bottom plate is arranged at the bottoms of the front cabinet 102 and the rear cabinet 101. In this scheme, each riser is to enclosing the cabinet body, improves the security.

Specifically, the pushing mechanism 50 is a pushing motor or a pushing cylinder, and a pushing plate is disposed at an output end of the pushing mechanism 50.

While the foregoing has been provided to illustrate the principles and embodiments of the present utility model, and while specific embodiments have been described herein, it will be apparent to those skilled in the art that various changes and modifications can be made therein without departing from the principles and embodiments of the utility model, the utility model is defined in the appended claims.

Claims (10)

1. The auxiliary automatic feeding device for wood door cutting is characterized by comprising a cabinet, wherein a lifting mechanism is arranged in the cabinet, an opening is formed in the front side of the cabinet, a lifting table is arranged at the opening of the cabinet, and the lifting table is driven by the lifting mechanism to lift; the left and right sides of the cabinet are respectively provided with a cutting frame for installing a cutting machine and a pushing mechanism for pushing the door plate, the front and rear sides of the lifting platform are respectively provided with a front conveying mechanism and a rear conveying mechanism, the cutting frame and the pushing mechanism are positioned on the two sides of the rear conveying mechanism and are provided with horizontal pushing holes, and the output end of the pushing mechanism pushes the door plate on the rear side of the lifting platform from left to right into the pushing holes to cut the door plate through the cutting machine installed on the cutting frame.

2. The auxiliary automatic feeding device for wooden door cutting according to claim 1, wherein the lifting mechanism is a screw lifter, the driving part of the screw lifter is a driving motor, and the driving motor is controlled by the control mechanism.

3. The auxiliary automatic feeding device for wooden door cutting according to claim 2, wherein the control mechanism comprises an angle sensor and a PLC controller, the angle sensor is meshed with an output shaft of the driving motor through a group of gears for reading the rotation angle, the angle sensor is connected with the PLC controller for feeding back the read angle information to the PLC controller, and the PLC controller is connected with the driving motor for controlling the operation of the driving motor.

4. The auxiliary automatic feeding device for wooden door cutting according to claim 2, wherein the control mechanism comprises a groove-shaped optical coupler sensor and a PLC controller, the groove-shaped optical coupler sensor comprises a groove-shaped optical coupler arranged on the cabinet and a shielding piece arranged on a lifting part of the screw lifter, and the shielding piece can extend into a position between a light emitting end and a receiving end of the groove-shaped optical coupler to shield light; the groove-type optical coupler sensor and the driving motor are connected with the PLC, the groove-type optical coupler sensor is used for feeding back the height position of the lifting part of the screw lifter to the PLC, and the PLC controls the driving motor to operate.

5. The auxiliary automatic feeding device for wooden door cutting according to claim 4, wherein the groove-shaped optocouplers are arranged at equal intervals, and the groove-shaped optocouplers are powered in a scanning mode.

6. The auxiliary automatic feeding device for wooden door cutting according to claim 1, wherein the front conveying mechanism and the rear conveying mechanism comprise a common frame, and a front conveyor and a rear conveyor which are arranged in the common frame, and each of the front conveyor and the rear conveyor comprises a conveying motor, a conveying roller and a conveying belt, and the conveying belt is sleeved on the conveying roller and driven by the conveying motor.

7. The auxiliary automatic feeding device for wooden door cutting as recited in claim 6, wherein the conveyor belts of the front conveyor and the rear conveyor are alternately arranged left and right, and the conveyor belts of the front conveyor and the rear conveyor have overlapping portions in the front-rear direction.

8. The auxiliary automatic feeding device for wooden door cutting according to claim 1, wherein the cutting frame is provided with a strip-shaped cutting opening, and the output end of the cutting machine is inserted through the cutting opening to cut the door panel below.

9. The auxiliary automatic feeding device for wooden door cutting according to claim 1, wherein the cabinet comprises a rear cabinet body and a front cabinet body, the lifting mechanism is arranged in the rear cabinet body, two upright posts are respectively arranged on two sides of the front end of the front cabinet body, connecting crosspieces are arranged on the lower sides of the two upright posts, and the lifting table extends into the front cabinet body from the front side of the connecting crosspieces through the upper part of the connecting crosspieces and extends into the rear cabinet body to be connected with the output end of the lifting mechanism.

10. The auxiliary automatic feeding device for wooden door cutting according to claim 9, wherein a front vertical plate is arranged below the connecting crosspiece, and a left vertical plate and a right vertical plate are respectively arranged between the vertical columns on the left side and the right side and the rear cabinet body; the bottoms of the front cabinet body and the rear cabinet body are provided with a bottom plate.