JP3188090U - Tube chamfering equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a tube chamfering apparatus which is suitable for mass flow production, can complete cutting and chamfering in one process, and has an effect of improving work efficiency and reducing working time. A tube chamfering apparatus is composed of three parts: a processing portion, a feed roller portion, and a stereotactic unloading portion. These three parts can have different structures, and the three parts can be connected by the rail 20. The processing unit includes a processing rack 1, a set of processing rollers 2 mounted in parallel on the processing rack 1 via bearings, and a drive motor 9 connected to the processing rollers 2. The processing rack 1 has a quadrangular frame structure, and two sets of bearings are installed at both front and rear ends of the upper surface of the processing rack 1, and one processing roller 2 is installed for each set of the two sets of bearings. The two processing rollers 2 are driven by a belt, a pulley, and a drive motor 9. [Selection diagram] Fig. 1

Description

  The present invention relates to a kind of tube chamfering apparatus.

  Tubes often used for grid construction, etc. must first be cut to an appropriate length when used. The section of the cut tube is perpendicular to the axis, and when parts are welded to the section of the tube, for example when welding a single piece of steel or section steel, the section of the tube is chamfered to ensure welding accuracy. It is absolutely necessary to perform processing. For this reason, at least two processes are required to process one tube, and a dedicated tool is required, or if there is no dedicated tool, the process becomes complicated and the processing cost increases, and mass production by flow work is required. There was a problem that it could not be realized and the work efficiency was lowered.

  An object of the present invention is to provide a tube chamfering apparatus that has a simple structure, is highly convenient, is suitable for mass flow production, and can improve work efficiency.

  In order to achieve the above object, the present invention adopts the following configuration.

  That is, the tube chamfering apparatus according to the present invention includes a processing rack and a set of processing rollers installed in the processing rack via bearings, and a drive motor is connected to the processing rollers. The feature is that a plasma cutting machine is disposed at the tip of the processing rack, and a lifting device is further installed. The lifting device includes a lift frame installed on a processing rack via a trunnion. The trunnion is positioned at an intermediate portion of the lift frame, and one end of the lift frame is provided with a processing lift roller via a bearing. A processing hydraulic cylinder is connected to the other end, and one end of the processing hydraulic cylinder is connected to the lift frame and the other end is connected to the processing rack.

  A feed roller portion is installed on the right end side (rear end side) of the processing rack. The feed roller unit includes a processing rack and a pair of processing rollers installed in parallel to the processing rack via bearings, and the processing roller and the processing roller of the processing unit are installed so as to extend in the same direction. Yes. A machining lift frame is installed at the left end (front end side) of the processing rack via a work trunnion, the work trunnion is located in the middle of the lift frame, and a lift roller is installed at one end of the lift frame via a bearing. ing. A processing hydraulic cylinder is installed at the other end of the lift frame. One end of the hydraulic cylinder is connected to the processing lift frame, and the other end of the hydraulic cylinder is connected to the processing rack.

  On the front end side (left side) of the processing rack of the processing unit, a stereotaxic unloading unit is installed. The localization unloading unit includes an unloading rack and a pair of unloading rollers installed in parallel to the unloading rack via bearings, so that the unloading roller and the processing roller of the processing unit face the same direction. is set up. The unload rack is further provided with an unload roller, and the two unload rollers are installed in parallel. An unloading claw is connected and fixed to one unloading roller, and an unloading hydraulic cylinder is installed between the unloading claw and the unloading rack. The unloading claw includes a main lever, a feed lever that extends vertically from the main lever, and is connected and fixed to the main lever, and a stop lever. The feed lever is connected and fixed to the unload roller. A trunnion block is installed on the main lever, and the trunnion block is further connected to an upper portion of the unload hydraulic cylinder. A positioning roller is installed on the left end (front end side) of the unload rack via a bearing, and the positioning roller and the unloading roller are arranged in parallel. The localization roller and the unloading roller are arranged so as to face the same direction, and a localization plate is connected and fixed to one end of the localization roller.

    With such a configuration, the tube chamfering processing apparatus according to the present invention is suitable for mass flow production, cutting and chamfering processing can be completed in one step, improving work efficiency and working time. It is possible to achieve an effect that it is possible to reduce this.

These are explanatory drawings of the structure concerning the Example of this invention.

These are the structure explanatory drawings of a processing part.

FIG. 3 is a plan view of FIG. 2.

These are the structure explanatory drawings of a feed roller.

These are explanatory drawings of the structure of the localization unloading device.

FIG. 3 is a right side sectional view of a localization unloading device.

These are the structure explanatory drawings of a plasma cutting device.

    The present invention will be described in detail below with reference to the drawings.

    As shown in FIG. 1, the tube chamfering apparatus according to the present invention is composed of three parts: a processing part, a feed roller part, and a localization unloading part. The three parts can have different structures, and the rails 20 can connect the three parts. In this case, the distance between the three portions can be adjusted according to the length of the tube.

    The functions of cutting and chamfering in the processed part will be described below. As shown in FIGS. 2 and 3, the processing unit is connected to the processing rack 1, a set of processing rollers 2 placed in parallel on the processing rack 1 via bearings, and the processing roller 2. Drive motor 9. The processing rack 1 has a rectangular frame structure, and two sets of bearings are installed at both front and rear ends of the upper surface of the processing rack 1, and one processing roller 2 is installed for each of the two sets of bearings. The two processing rollers 2 are driven by a belt, a pulley, and a drive motor 9. In this case, the drive motor 9 can be driven to rotate in the same direction while synchronizing the two processing rollers 2. On the other hand, a plasma cutting machine 4 is installed on the left end of the processing rack 1 via the rack 3. As shown in FIG. 7, the rack 3 forms a triangular rack fixedly connected to the processing rack 1. An upper portion of the rack 3 is connected to a processing lever 2 and a rack lever 31 extending in a vertical direction, and a spring 32 is installed between the rack lever 31 and the rack 3. The plasma cutting machine 4 is fixed to the rack lever by bolting or strapping. A roll 33 is installed at the end of the rack 3 via a bearing. When cutting the tube, the roll 33 is pushed in the tube direction, the tube position is adjusted, the angle of the plasma cutting machine is adjusted and pressed, and the tube is rotated to cut the tube. At this time, it is possible to perform chamfering with a certain angle in the cross section. A lifting device is installed at the left end of the processing rack 1, and the lifting device includes a lift frame 5 installed on the processing rack 1 via a trunnion, and the trunnion is located at an intermediate portion of the lift frame 5. A processing lift roller 6 is installed at one end via a bearing, and a processing hydraulic cylinder 7 is installed at the other end. One end of the processing hydraulic cylinder 7 is connected to the lift frame 5, and the other end side is connected to the processing rack 1.

    In this case, the hydraulic cylinder 7 drives the lift frame 5 in the vertical direction and the lift roller 6 in the vertical direction during processing.

    The feed roller portion is used to transport the tube waiting for processing forward (leftward in FIG. 1). The feed roller portion is installed at the right end of the processing rack 1 in the processing portion. As shown in FIG. 4, the feed roller unit includes a processing rack 8 and a pair of processing rollers 81 installed in parallel to the rack 8 via bearings. The processing roller 81 and the processing roller 2 of the processing unit are the same. It is installed to extend in the direction. A processing lift frame 82 is installed at the left end of the processing rack 8 via a work trunnion. The work trunnion is located in the middle of the lift frame 82, and a lift roller 83 is installed at one end of the lift frame 82 via a bearing. Has been. A processing hydraulic cylinder 84 is installed at the other end of the lift frame 82. One end of the hydraulic cylinder 84 is connected to the processing lift frame 82, and the other end side of the hydraulic cylinder 84 is connected to the processing rack 8.

    As a function of the stereotaxic unloading part, one is to determine the length of the tube to be cut, and the second is to support the front end side of the tube when the tube is cut by the plasma cutting machine 4 And holding the tube after cutting is complete.

The stereotaxic unloading part is arranged on the left end side of the machining rack 1 in the machining part, and the distance between the stereotaxic unloading part and the machining rack 1 can be adjusted by the required cutting length of the tube. As shown in FIG. 5, the stereotaxic unloading unit includes an unloading rack 10 and a pair of unloading rollers 101 installed in parallel to the unloading rack 10 via bearings. The processing roller 2 is installed so as to face in the same direction.
As shown in FIGS. 5 and 6, an unload roller 102 is further installed on the unload rack 10 via belling, and the unload roller 102 and the unload roller 101 are arranged in parallel.

    An unload claw is connected and fixed to the unload roller 102, and an unload hydraulic cylinder 103 is installed between the unload claw and the unload rack 10. The unloading claw is provided with a main lever 104, a feed lever 105 extending vertically from the main lever 104 and coupled and fixed to the main lever 104, and a stop lever 106, and the feed lever 105 is coupled and fixed to the unload roller 102. Has been. A trunnion block 107 is installed on the main lever 104, and the trunnion block 107 is further connected to an upper portion of the unload hydraulic cylinder 103. It is desirable to install one unloading claw at least on each side of the unloading rack 10. The number of unload hydraulic cylinders used in combination with the unload claw can be changed as required.

    A localization roller 108 is installed at the left end of the unload rack 10 via a bearing, and the localization roller 108 and the unload roller 101 are installed in parallel. The localization roller 108 and the unloading roller 101 are arranged so as to face in the same direction, and a localization plate 109 is connected and fixed to one end of the localization roller 108.

In use, the tube waiting for processing is placed on the processing roller 2, and both the processing roller 81 and the unload roller 101 face the same direction as the processing roller 2. Is also placed on the processing roller 81 and the unloading roller 101. The relative position of the processing rack 1 between the localization unloading portion and the processing portion is adjusted, and the tip of the tube (the left end in FIG. 1) is applied to the localization plate 109.
Then, the drive motor 9 is activated to synchronize the two processing rollers 2 and rotate in the same direction to rotate the tube. At that time, by starting the plasma cutting machine 4, the tube can be cut and a certain chamfering process can be performed.
In this case, the tube arranged in the stereotaxic unloading portion is a product that has been cut, and by operating the unloading hydraulic cylinder 103, the unloading hydraulic cylinder 103 raises the main lever 104, and the main lever 104 The unload roller 102 is rotated via the feed lever 105, and the unload hydraulic cylinder 103 raises the main lever 104. Then, the main lever 104 rotates the unload roller 102 via the feed lever 105 to drive synchronously with other unload claws connected to the unload roller 102, and lifts the tube that has been cut off. Slide along and drop it onto the floor. Here, the stop lever 106 has a function of preventing the cut tube from dropping on the opposite side.

    After completion of the cutting, tubes waiting to be processed are left in the processing section and the feed roller section, and by using the lever principle by simultaneously driving the hydraulic cylinder 7 and the processing hydraulic cylinder 84, The processing lift roller 83 is raised. When the processing lift roller 6 and the processing lift roller 83 rise, the tube waiting for processing rises and separates from the processing roller 2 and the unload roller 101. At this time, the operator can easily move the tube waiting for processing forward (leftward in FIG. 1). Then, the tip of the tube waiting for processing (the left side in FIG. 1) is moved until it comes into contact with the localization plate 109, and then the processing hydraulic cylinder 7 and the processing hydraulic cylinder 84 are moved until the tube contacts the unload roller 101 and is placed. After returning to the original position, it waits for the next process.

Claims (3)

A tube chamfering device,
Processing rack (1),
A set of processing rollers (2) mounted on the processing rack (1) via bearings;
A processing unit comprising a drive motor (9) connected to the processing roller (2);
A plasma cutting machine (4) is installed on the front end side of the processing rack (1) via a frame (3).
A lifting device is further installed on the front end side of the processing rack (1).
The lifting device includes a lift frame (5) installed on the processing rack (1) via a trunnion, and the trunnion is located at an intermediate portion of the frit frame (5) and is attached to one end of the lift frame (5). Is equipped with a machining hydraulic cylinder (7), one end of the machining hydraulic cylinder (7) is connected to the lift frame (5), and the other end is connected to the processing rack (1). Processing equipment. The tube chamfering processing apparatus according to claim 1,
A feed roller section is installed on the rear end side of the processing rack (1).
The feed roller part
Processing rack (8),
A set of processing rollers (81) attached to the processing rack (8) in parallel via a bearing is provided, and the processing rollers (81) are arranged in the same direction as the processing rollers (2) of the processing portion. In addition, a processing frit frame (82) is installed on the front end side of the processing rack (8) via a work trunnion, and the work trunnion is located at an intermediate portion of the lift frame (82), A machining lift roller (83) is installed at one end, a machining hydraulic cylinder (84) is installed at the other end of the lift frame (5), and one end of the machining hydraulic cylinder (84) is installed at the machining lift frame (82). And the other end side of the processing hydraulic cylinder (84) is connected to the processing rack (8). The tube chamfering processing apparatus according to claim 1 or 2,
At the front end side of the processing rack (1), a stereotaxic unloading part is installed,
The localization unloading section
An unload rack (10);
Provided with a pair of unload rollers (101) installed in parallel to the unload rack (10) via bearings, so that the unload roller (101) and the processing roller (2) of the processing section face the same direction The unload claw is connected and fixed to the unload roller (102), and an unload hydraulic cylinder (103) is installed between the unload claw and the unload rack (10).
The unloading claw is provided with a main lever (104), a feed lever (105) that extends vertically from the main lever (104) and is connected and fixed to the main lever (104), and a stop lever (106). The lever (105) is connected and fixed to the unload roller (102), and the main lever (104) is provided with a trunnion block (107). The trunnion block (107) is connected to the upper portion of the unload hydraulic cylinder, and is unloaded. A positioning roller (108) is installed on the front end side of the load rack (10) via a bearing, and the positioning roller (108) and the unloading roller (101) are installed in parallel, and the positioning roller (108) and the unloading roller are installed. (101) are arranged so that they face in the same direction, and the stereotaxic plate (109) Tube chamfering apparatus characterized by being connected and fixed.

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