The present invention relates to a beveling machine which is designed to cut a bevel of uniform dimensions along one or both edges of a workpiece, such as a floor strip with tongue and groove edges.
Such flooring strips are not always of uniform straightness, thickness, and width, and when the individual strips are formed into a finished floor, there can be raised edges which can catch the heel of a person walking on the surface. To alleviate this problem, it has been conventional to cut a small bevel along each upper edge of the flooring strips, utilizing a cutting wheel which is mounted along each side of a conveyor which serially advances the flooring strips past the cutting wheels. However, this prior practice is not entirely satisfactory since the non-uniformity of the flooring strips results in a non-uniform bevel.
It is accordingly an object of the present invention to provide a beveling machine which is adapted to cut a bevel along one or both edges of a workpiece as the workpiece is advanced along a linear path of travel, and wherein the bevel is of uniform dimensions along the edge of the workpiece.
The above and other objects and advantages of the invention are achieved by the provision of a beveling apparatus which comprises a motor assembly which includes a cutting wheel, and means mounting the motor assembly adjacent the path of travel of the workpiece as it is advanced along the path of travel by a conveyor, with the cutting wheel contacting the edge of the advancing workpiece. Also, the motor assembly is mounted to permit floating movement of the motor assembly in a direction toward and away from the edge of the workpiece as the workpiece is advanced along the path of travel.
A guide shoe is fixed to the motor assembly and positioned to ride on the advancing workpiece and so that the guide shoe and the cutting wheel follow the contour of the edge of the advancing workpiece and thereby cause a uniform bevel to be formed along the edge of the advancing workpiece.
In a preferred embodiment, the cutting wheel of the motor assembly is mounted to a rotatable draft shaft which extends in a horizontal direction which is substantially perpendicular to the path of travel of the workpiece, and the motor assembly is configured to permit separate floating movement in two directions, namely an in and out first direction which is parallel to the axis of the drive shaft and in an up and down or vertical second direction. Also, a manual adjustment of the motor assembly toward and away from the workpiece along the first direction is possible, and a separate manual adjustment of the motor assembly up and down along the second direction is also possible.
Also in a preferred embodiment, the invention comprises a second beveling apparatus which is configured to correspond to the structure and function of the above described beveling apparatus, and which is positioned on the side of the workpiece conveyor opposite the side on which the above described beveling apparatus is positioned. This permits the opposite edges of the workpieces to be concurrently beveled as they are serially advanced by the conveyor along the path of travel.
Some of the objects and advantages of the present invention having been stated, others will appear as the description proceeds when considered in conjunction with the accompanying drawings, in which
Referring more particularly to the drawings, a workpiece beveling apparatus 10 is illustrated which is positioned on one side of a conveyor 12 for serially advancing the workpieces W, which in this case are flooring strips having tongue and groove edges, along a horizontal linear path of travel. The conveyor 12 is conventional and is composed of a segmented belt 13 with hold down rollers 14, note
The apparatus 10 is designed to cut a bevel B along one top edge of the advancing flooring strips as best seen in
The apparatus 10 comprises a motor assembly 16 mounted on a fixed frame 17 on one side of the conveyor 12, and the motor assembly 16 includes a horizontal support plate 18 which mounts an electric motor 19. The electric motor 19 has a drive shaft 20 which extends in a generally horizontal direction which is perpendicular to the path of travel defined by the conveyor 12. A conventional cutting wheel 22 is mounted on the end of the drive shaft 20 so as to rotate in a plane which is generally vertical and parallel to the path of travel. Also, the cutting wheel 22 is mounted so as to contact the upper edge of the advancing workpieces W and cut a bevel B, as further described below.
The motor assembly 16 is mounted by a mounting arrangement which includes a first linear slide assembly 24 which permits manual adjustment of the motor assembly 16 toward and away from the path of travel along a first direction which is substantially parallel to the axis of the drive shaft 20. The first linear slide assembly 24 also permits the motor assembly 16 to float against spring biasing forces a limited distance toward and away from the workpiece along the first direction, in a manner further described below.
The mounting arrangement of the motor assembly 16 also includes second and third linear slide assemblies 25, 26 which are connected to each other in parallel, and which permit manual adjustment in an up and down or second vertical direction. The second and third linear slide assemblies 25, 26 also permit the motor assembly 16 to float against spring biasing forces a limited distance up and down along the second direction, as described in detail below.
The second and third linear slide assemblies 25, 26 are of like construction, and only the second assembly 25 will be described herein with reference to
As illustrated in
The second slide assembly 25 further includes a vertically disposed guide rail 35 which is fixed between the end plates 30, 31, and a micrometer 37 is mounted to the end plate 30 for the purpose of accurately sensing the rotational position of the screw 33 and thus the hand wheel 32. The micrometer 37 thus visually indicates the height of the cutter relative to the workpiece.
The second slide assembly 25 mounts an adjustable slide housing 39 which is mounted for vertical movement along the rail 35 and the screw 33. The slide housing 39 is composed of a box-like rectangular frame which consists of two opposite side plates 41, 42 and top and bottom plates 43, 44. The screw 33 threadedly engages one or both of the top and bottom plates 43, 44, so that upon rotation of the screw the frame of the slide housing 39 moves up or down along the rail 35.
Within the slide housing 39 there is mounted a slide 46 which includes a guide plate 47 which directly engages the rail 35 via suitable bearings, so that the slide 46 is free to move up and down along the rail. The slide also has a mounting plate 48 which is fixed to the guide plate 47 as best seen in
Two positioning spring assembles 51, 52 are mounted in the top plate 43 and engage the upper end of the mounting plate 48, and two positioning spring assemblies 53, 54 are mounted in the bottom plate 44 and engage the lower end of the mounting plate 48. The four spring assemblies are of like construction and each includes a plunger 55 which is axially biased outwardly by an internal spring 56. The force of the spring acting on the plunger is controlled by a cap screw 57 which may be engaged and rotated by a suitable tool T which extends through an opening in the top or bottom plate as illustrated in
As will be apparent, the mounting plate 48 of each slide 46 is held between the spring assemblies 51–54 so as to permit a limited floating movement against a spring biasing force in both the up and down directions.
The mounting plate 48 of each slide assembly 25, 26 is fixed to an inverted U-shaped bracket 60, which in turn supports the first linear slide assembly 24 thereupon, note
In the case of the second and third linear slide assemblies 25, 26, it will be seen from
From the above, it will be seen that rotation of the hand wheel of either of the second and third slide assemblies 25, 26 causes both slide housings 39 and thus the motor assembly 16 to move up or down, and the positioning of the slide housing and motor assembly may thereby be manually adjusted in the vertical direction. The back plate 29 of the second slide assembly 25 may have a scale printed thereon to facilitate the placement of the motor assembly at a desired elevation, note
Similarly, rotation of the hand wheel of the first slide assembly 24 causes the slide housing 39 and the motor assembly 16 to move in and out along a direction parallel to the axis of the drive shaft 20, and a scale may be printed on the back plate to indicate its position, note
The edge of the support plate 18 of the motor assembly which is adjacent the conveyor 12 mounts a guide shoe 65 which is positioned to engage and ride on each advancing workpiece. The guide shoe 65 includes a horizontal, downwardly facing first contact surface 66 which is positioned to engage the top surface of the workpiece, and a vertical second contact surface 67 which is positioned to engage the side edge of each advancing workpiece. The second guide surface 67 is substantially aligned with and axially inside of the plane of the cutting wheel 22, and the first guide surface 66 is positioned on a bar 68 which is axially beyond the plane defined by the cutting wheel.
The guide shoe 65 is mounted to the support plate 18 of the motor assembly 16 so that the cutting wheel is located in the opening formed between the outer bar 68 and the main body of the guide shoe, and so as to permit manual adjustment of the guide shoe toward and away from the cutting wheel in a direction which is substantially parallel to the axis of the rotatable drive shaft 20. This mounting arrangement includes a pair of parallel threaded members 70 which are mounted on the support plate 18 for free rotation and which, are threadedly joined to the rear sides of the shoe 65, note
As part of the machine set-up, the operator initially adjusts the positioning of the guide shoe 65 on the support plate 18 so as to properly engage the particular workpieces W to be beveled. Next, the operator adjusts the hand wheel 32 of the first linear slide assembly 24 to set the cutting wheel 22 at the proper position in the in and out direction with respect to the size of the workpieces, and the operator also adjusts the hand wheel of the closest of the second and third linear slide assemblies 25, 26 to set the cutting wheel 22 at the proper position in the up and down direction.
The conveyor 12 and the motor 19 are then activated, so that the workpieces W are serially conveyed along a horizontal path of travel past the rotating cutting wheel 22. The second contact surface 67 of the guide shoe rides on the adjacent edge of each workpiece (note
The first contact surface 66 of the guide shoe 65 rides on the top of each workpiece (note
As schematically illustrated in
Many modifications and other embodiments of the invention set forth herein will come to mind to one skilled in the art to which this invention pertains having the benefit of the teachings presented in the foregoing description and the associated drawings. For example, the apparatus 10 as specifically illustrated herein is configured to move and float in two directions, i.e. in and out and up and down, but the apparatus could be configured to move and float in a single direction, e.g. in a direction perpendicular to the beveled surface being formed on the workpieces. Therefore, it is to be understood that the invention is not to be limited to the specific embodiment disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
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Number | Date | Country |
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101 16 381 | Apr 2001 | DE |
Number | Date | Country | |
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20050175424 A1 | Aug 2005 | US |