CN115194637A - Directional polishing device and method for basalt fiber composite pipe - Google Patents
Directional polishing device and method for basalt fiber composite pipe Download PDFInfo
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- CN115194637A CN115194637A CN202211118799.5A CN202211118799A CN115194637A CN 115194637 A CN115194637 A CN 115194637A CN 202211118799 A CN202211118799 A CN 202211118799A CN 115194637 A CN115194637 A CN 115194637A
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- fiber composite
- basalt fiber
- composite pipe
- polishing
- distance
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B29/00—Machines or devices for polishing surfaces on work by means of tools made of soft or flexible material with or without the application of solid or liquid polishing agents
- B24B29/02—Machines or devices for polishing surfaces on work by means of tools made of soft or flexible material with or without the application of solid or liquid polishing agents designed for particular workpieces
- B24B29/06—Machines or devices for polishing surfaces on work by means of tools made of soft or flexible material with or without the application of solid or liquid polishing agents designed for particular workpieces for elongated workpieces having uniform cross-section in one main direction
- B24B29/08—Machines or devices for polishing surfaces on work by means of tools made of soft or flexible material with or without the application of solid or liquid polishing agents designed for particular workpieces for elongated workpieces having uniform cross-section in one main direction the cross-section being circular, e.g. tubes, wires, needles
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B41/00—Component parts such as frames, beds, carriages, headstocks
- B24B41/06—Work supports, e.g. adjustable steadies
- B24B41/067—Work supports, e.g. adjustable steadies radially supporting workpieces
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B47/00—Drives or gearings; Equipment therefor
- B24B47/10—Drives or gearings; Equipment therefor for rotating or reciprocating working-spindles carrying grinding wheels or workpieces
- B24B47/12—Drives or gearings; Equipment therefor for rotating or reciprocating working-spindles carrying grinding wheels or workpieces by mechanical gearing or electric power
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24B—MACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
- B24B49/00—Measuring or gauging equipment for controlling the feed movement of the grinding tool or work; Arrangements of indicating or measuring equipment, e.g. for indicating the start of the grinding operation
- B24B49/12—Measuring or gauging equipment for controlling the feed movement of the grinding tool or work; Arrangements of indicating or measuring equipment, e.g. for indicating the start of the grinding operation involving optical means
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P40/00—Technologies relating to the processing of minerals
- Y02P40/50—Glass production, e.g. reusing waste heat during processing or shaping
- Y02P40/57—Improving the yield, e-g- reduction of reject rates
Landscapes
- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Finish Polishing, Edge Sharpening, And Grinding By Specific Grinding Devices (AREA)
- Grinding Of Cylindrical And Plane Surfaces (AREA)
Abstract
The invention discloses a directional polishing device and method for a basalt fiber composite pipe, and relates to the technical field of processing of basalt fiber composite pipes. In the invention: the cylinder assembly comprises a propelling shaft rod and a clamping plate arranged at the tail end of the propelling shaft rod. All the cylinder assemblies at the same side position of the basalt fiber composite pipe are connected with the same gas source through pneumatic pipelines, and the gas source synchronously transmits gas sources with the same pressure to all the cylinder assemblies. The photoelectric distance sensing module is arranged in the area between the two inclined clamping assemblies at the upper side position and comprises a plurality of photoelectric probes arranged without gaps. The rotating shaft rod is connected with the polishing wheel and a bearing sleeve positioned at the outer side of the polishing wheel, and the sliding sleeve is inserted at the position of a pipe cavity at the side end of the basalt fiber composite pipe. The device can quickly and accurately 'align' and fixedly clamp the basalt fiber composite pipe on the conveyor belt, and stably and accurately polish the side end of the basalt fiber composite pipe.
Description
Technical Field
The invention relates to the technical field of basalt fiber composite pipe processing, in particular to a device and a method for directionally polishing a basalt fiber composite pipe.
Background
After preliminary production of basalt fiber composite pipe is completed, certain burrs exist on end faces of two sides of the pipe body, if the long section of the side end of the basalt fiber composite pipe is directly cut off through a cutting machine, more basalt fiber composite pipes are wasted, the long pipe body at one end is cut off, and the length of the pipe body is possibly not up to standard. If the length of the cut pipe body is shorter, the cutting machine is not easy to operate.
When the side end of the basalt fiber composite pipe is polished, the basalt fiber composite pipe conveyed on the conveying belt is not straightened, the basalt fiber composite pipe on the conveying belt needs to be straightened before polishing, the side end of the basalt fiber composite pipe is greatly influenced by vibration during polishing, and if the fixed position of the basalt fiber composite pipe is far away from the side end of the basalt fiber composite pipe after straightening, the polishing error is large.
In conclusion, how to perform fast and accurate 'straightening' and fixed clamping on the basalt fiber composite pipe on the transmission belt and perform stable and accurate polishing on the side end of the basalt fiber composite pipe becomes a problem to be solved.
Disclosure of Invention
The invention aims to provide a device and a method for directionally polishing a basalt fiber composite pipe, so that the basalt fiber composite pipe on a transmission belt is quickly and accurately aligned and fixedly clamped, and the side end of the basalt fiber composite pipe is stably and accurately polished.
In order to solve the technical problems, the invention is realized by the following technical scheme:
the invention provides a basalt fiber composite pipe directional polishing device which comprises a transmission supporting belt used for directionally transmitting a basalt fiber composite pipe, wherein the width dimension of the transmission supporting belt is smaller than the length dimension of the basalt fiber composite pipe, a group of inclined clamping components are arranged at the upper position and the lower position of the side end of the basalt fiber composite pipe, each inclined clamping component comprises a directional moving rod and a linear motor slidably mounted on the directional moving rod, a cylinder component is mounted on the linear motor towards the position of the basalt fiber composite pipe, and each cylinder component comprises a propelling shaft rod and a clamping plate mounted at the tail end of the propelling shaft rod. All the air cylinder assemblies at the same side position of the basalt fiber composite pipe are connected with the same air source through pneumatic pipelines, the air source synchronously transmits air sources with the same pressure to all the air cylinder assemblies, and the air source is provided with a pressure reducing valve. The area between the two inclined clamping assemblies at the upper side position is provided with a photoelectric distance sensing module, and the photoelectric distance sensing module comprises a plurality of photoelectric probes which are arranged without gaps. The transmission supporting belt is provided with transverse moving driving devices in the positions of two sides, the output side of each transverse moving driving device is connected with a polishing motor, the output side of each polishing motor is provided with a rotating shaft rod, the rotating shaft rods are connected with polishing wheels and bearing sleeves located at the outer side positions of the polishing wheels, sliding sleeves are fixedly installed on the peripheries of the bearing sleeves, and the sliding sleeves are inserted into pipe cavity positions at the side ends of the basalt fiber composite pipes.
As a preferred technical scheme of the directional polishing device in the invention: all fixed mounting has a connection flat board between two oblique position centre gripping subassemblies in upside position, two oblique position centre gripping subassemblies in downside position, linear electric motor and connection flat board fixed connection, and photoelectricity is apart from sensing module and is installed in the dull and stereotyped intermediate position of upside position connection.
As a preferred technical scheme of the directional polishing device in the invention: the distance between the two clamping plates in the same vertical direction at the initial position is larger than the outer diameter of the basalt fiber composite pipe.
As a preferred technical scheme of the directional polishing device in the invention: the included angle between two inclined clamping assemblies at the same height position is larger than 45 degrees.
As a preferred technical scheme of the directional polishing device in the invention: the rotating shaft rod ring side is provided with a fixed disc, the polishing wheel comprises an inner ring plate and an outer polishing ring plate, and the inner ring plate and the fixed disc are fixedly connected. And the outer diameter of the polishing outer ring plate is larger than that of the basalt fiber composite pipe.
As a preferred technical scheme of the directional polishing device in the invention: the bearing housing includes inner race, outer bearing ring, and the inner race fixed connection of swivel spindle and bearing housing slides sleeve and bearing housing's outer bearing ring fixed connection.
As a preferred technical scheme of the directional polishing device in the invention: the bearing sleeve side is provided with a shaft end threaded hole, the sliding sleeve side is provided with a threaded through hole, and the threaded through hole and the shaft end threaded hole are provided with axis bolts.
The invention provides a directional polishing method for a basalt fiber composite pipe, which comprises the following steps:
(1) Clamping the end part of the basalt fiber composite pipe: the transmission supporting belt drives the basalt fiber composite pipe to advance, when any one photoelectric probe senses that any one end of the basalt fiber composite pipe enters the vertical sensing detection range of the photoelectric probe and the distance sensed by the photoelectric probe is not more than the 'entering clamping distance' preset by the system, two air cylinder assemblies at the upper side position and two air cylinder assemblies at the lower side position of the current side end simultaneously act to position and clamp the current side end of the basalt fiber composite pipe. And the distance between any photoelectric probe at the position of the other side end of the basalt fiber composite pipe and the basalt fiber composite pipe is sensed and detected, the distance is compared with the 'entering clamping distance' for judgment, and the cylinder assembly at the position of the other side end of the basalt fiber composite pipe is used for positioning and clamping the other side end of the basalt fiber composite pipe.
(2) Side end position finding: the photoelectric probes of the photoelectric distance sensing module downwards detect the distance of the basalt fiber composite tube, the position of the photoelectric probe with the first distance detection larger than the tube end distance preset by the system is analyzed and judged along the direction from the middle part to the side end of the basalt fiber composite tube, and the photoelectric probe at the position is marked as a polishing starting photoelectric probe. After the two side ends of the basalt fiber composite pipe in the step (1) are positioned and clamped, when the side end is searched in the step (2), all photoelectric probes at any side end position of the basalt fiber composite pipe do not sense and detect that the distance is larger than the preset pipe end distance of the system, the air cylinder assembly at the current side end of the basalt fiber composite pipe returns to the initial position, and the linear motor drives the photoelectric distance sensing module and the air cylinder assembly to translate towards the side end of the basalt fiber composite pipe until a distance parameter sensed and detected by one photoelectric probe is larger than the preset pipe end distance of the system.
(3) Polishing and positioning: and analyzing and judging the position of the photoelectric probe opposite to the basalt fiber composite pipe end surface in the vertical direction when the polishing is finished according to the polishing propelling depth preset by the system and the sensing distance distributed among the photoelectric probes, wherein the photoelectric probe at the position is marked as a polishing finished photoelectric probe.
(4) Polishing the side end of the basalt fiber composite pipe: and (3) the transverse moving driving device pushes the polishing motor to push the polishing motor to the basalt fiber composite pipe, the sliding sleeve is inserted into the pipe cavity of the basalt fiber composite pipe, and when the distance information sensed by the polishing start photoelectric probe in the step (2) is not more than the pipe end distance preset by the system, the polishing motor drives the polishing wheel to rotate to start polishing the side end of the basalt fiber composite pipe. And (4) stopping polishing when the distance sensed by the polishing-finished photoelectric probe in the step (3) is a polishing short distance, driving a polishing motor to return by a transverse moving driving device, separating the sliding sleeve from the basalt fiber composite tube, driving the clamping plate to return to the initial position by the air cylinder assembly, and continuously conveying the polished basalt fiber composite tube by the transmission supporting belt forwards.
Compared with the prior art, the invention has the beneficial effects that:
according to the invention, the basalt fiber composite pipe can be clamped quickly in a pre-judging manner through the detection and matching of the photoelectric distance sensing module and the positioning and clamping of the inclined clamping assembly on the basalt fiber composite pipe, the side end face of the basalt fiber composite pipe in the motion process can be polished in a linear and positioning manner stably and accurately, and the phenomenon that the polishing error is increased due to the fact that the side end of the basalt fiber composite pipe is influenced by polishing vibration in the polishing process is avoided.
Drawings
FIG. 1 is a schematic view of the overall structure of the apparatus of the present invention.
Fig. 2 is a schematic view of a part a of fig. 1.
FIG. 3 is a schematic structural diagram of a polishing motor, a polishing wheel, a bearing housing and a sliding sleeve in the present invention.
FIG. 4 is a schematic view of the traversing driving device of the invention pushing the bearing sleeve and the sliding sleeve to be inserted into the pipe cavity at the side end of the basalt fiber composite pipe.
FIG. 5 is a schematic structural view of the basalt fiber composite pipe of the present invention for pre-judging, positioning and clamping.
Fig. 6 is a schematic diagram of the photoelectric probe performing cooperative sensing detection when the basalt fiber composite pipe is polished.
Description of the reference numerals:
1-driving a supporting belt; 2-basalt fiber composite pipe, 201-vertical symmetry plane; 3-inclined clamping assembly, 301-directional moving rod, 302-linear motor, 303-cylinder assembly, 304-propelling shaft rod, 305-clamping plate and 306-connecting flat plate; 4-photoelectric distance sensing module, 401-photoelectric probe; 5-a transverse moving driving device, 501-a transverse moving shaft rod; 6-polishing motor, 601-rotating shaft lever, 602-fixing disc; 7-polishing wheel, 701-installing an inner ring plate, 702-polishing an outer ring plate; 8-bearing sleeve, 801-shaft end threaded hole; 9-sliding sleeve, 901-threaded through hole; 10-axis bolt; 11-pneumatic lines; 12-a gas source; 13-pressure relief valve.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the invention.
Example one
Referring to fig. 1, a transmission supporting belt 1 directionally transports basalt fiber composite pipes 2, the length dimension of the directionally transported basalt fiber composite pipes 2 is larger than the width dimension of the transmission supporting belt 1, and the basalt fiber composite pipes 2 are exposed at two sides of the transmission supporting belt 1. A group of inclined clamping components 3 (combined with figure 5) are arranged above and below the side end of the basalt fiber composite pipe 2. The inclined clamping assembly 3 comprises a directional moving rod 301, a linear motor 302 and a cylinder assembly 303, wherein the linear motor 302 is slidably mounted on the directional moving rod 301. The transverse moving driving device 5 is located on two side directions of the transmission supporting belt 1, the polishing motor 6 is installed at the tail end of a transverse moving shaft of the transverse moving driving device 5, a rotating shaft 601 is arranged on the output side of the polishing motor 6, the rotating shaft 601 is connected with the polishing wheel 7 and a bearing sleeve 8 located on the outer side of the polishing wheel 7, and a sliding sleeve 9 is fixedly installed on the periphery of the bearing sleeve 8.
Referring to fig. 2 and 3, the fixed plate 602 is fixedly disposed at a position on an annular side of the rotating shaft 601, the polishing wheel 7 is fixedly connected at an outer side position of the fixed plate 602, the polishing wheel 7 includes an inner mounting ring plate 701 and an outer polishing ring plate 702, and an outer diameter of the outer polishing ring plate 702 is larger than an outer diameter of the basalt fiber composite pipe 2. The bearing sleeve 8 comprises an inner bearing ring and an outer bearing ring, the rotating shaft 601 is fixedly connected with the inner bearing ring of the bearing sleeve 8, and the sliding sleeve 9 is fixedly connected with the outer bearing ring of the bearing sleeve 8. The bearing sleeve 8 side is seted up axle head screw hole 801, and the slip sleeve 9 side is seted up screw through hole 901, and axis bolt 10 is installed at screw through hole 901, axle head screw hole 801 position.
Referring to fig. 4, after the inclined clamping assembly 3 clamps the basalt fiber composite pipe 2, the traverse driving device 5 pushes the polishing motor 6 and the sliding sleeve 9 to move transversely through the traverse shaft 501, and the sliding sleeve 9 is inserted into the pipe cavity at the side end of the basalt fiber composite pipe 2.
Referring to fig. 5, a photoelectric distance sensing module 4 is further installed between a set of inclined clamping assemblies 3 at an upper position. The connection flat plate 306 is fixedly connected with the linear motor 302, the included angle between the two inclined clamping components 3 connected with the same connection flat plate 306 is larger than 45 degrees, the photoelectric distance sensing module 4 is located in the middle of the connection flat plate 306 at the upper position and vertically detects downwards, the output end of the air cylinder component 303 is provided with the propelling shaft rod 304, the tail end of the propelling shaft rod 304 is provided with the clamping plate 305, and the distance between the two clamping plates 305 in the same vertical direction at the initial position is larger than the outer diameter of the basalt fiber composite tube 2. All the cylinder assemblies 303 at the same side position of the basalt fiber composite pipe 2 are connected with the same gas source 12 through the pneumatic pipeline 11, the gas source 12 synchronously transmits gas sources with the same pressure to all the cylinder assemblies 303, namely, the pneumatic driving force received by the upper cylinder assembly 303 and the lower cylinder assembly 303 at the same side position is the same, thereby synchronously completing the propelling and the return motion, the gas source 12 is provided with a pressure reducing valve 13, when the outer diameter of the basalt fiber composite pipe 2 is overlarge, the cylinder assemblies 303 drive the clamping plate 305 to move, the excessive air pressure can be released, and the excessive extrusion damage to the basalt fiber composite pipe 2 can not be formed.
Referring to fig. 6, the photoelectric distance sensing module 4 is provided with a plurality of closely arranged photoelectric probes 401, and the photoelectric probes 401 sense and detect the distance between the basalt fiber composite pipe 2 and the polished outer ring plate 702.
Example two
The invention relates to a directional polishing method of a basalt fiber composite pipe 2, which comprises the following specific contents:
in the first step, the end part of the basalt fiber composite pipe 2 is clamped
The transmission supporting belt 1 drives the basalt fiber composite pipe 2 to advance, when any one of the photoelectric probes 401 senses and detects that any one end of the basalt fiber composite pipe 2 enters a vertical sensing detection range of the photoelectric probe 401 and a distance sensed and detected by the photoelectric probe 401 is not more than a clamping distance preset by a system (the system refers to a control system formed by a single chip microcomputer or an industrial computer), wherein the clamping distance is not more than the clamping distance when a vertical symmetrical plane 201 of the basalt fiber composite pipe 2 enters a clamping range of an initial position clamping plate 305, the distance sensed and detected by the photoelectric probe 401 is not more than the clamping distance, such as a detection distance L in figure 5, two cylinder assemblies 303 at an upper side position and two cylinder assemblies 303 at a lower side position of a current side end simultaneously act to position and clamp the current side end of the basalt fiber composite pipe 2. And (3) sensing and detecting the distance between any photoelectric probe 401 at the position of the other side end of the basalt fiber composite pipe 2 and the basalt fiber composite pipe 2, comparing and judging the distance with the 'entering clamping distance', and finishing positioning and clamping on the other side end of the basalt fiber composite pipe 2 through a cylinder assembly 303 at the position of the other side end of the basalt fiber composite pipe 2.
And in the second link, the position of the 2 side end of the basalt fiber composite pipe is searched
The photoelectric probes 401 of the photoelectric distance sensing module 4 perform distance detection on the basalt fiber composite tube 2 downwards, and along the direction from the middle part to the side end of the basalt fiber composite tube 2, the position of the photoelectric probe 401 at which the first distance detection is greater than the preset "tube end distance" (the "tube end distance" is the distance between the photoelectric probe and the highest point of the basalt fiber composite tube 2, such as the distance "H" in fig. 4) is analyzed and judged, and the photoelectric probe 401 at this position is recorded as a "polishing start photoelectric probe". After the two side ends of the basalt fiber composite pipe 2 in the first link are positioned and clamped, when the middle side end in the second link is positioned, all photoelectric probes 401 at any side end position of the basalt fiber composite pipe 2 do not sense and detect that the distance is larger than the preset pipe end distance of the system, the cylinder assembly 303 at the current side end of the basalt fiber composite pipe 2 returns to the initial position, the linear motor 302 drives the photoelectric distance sensing module 4 and the cylinder assembly 303 to translate towards the position of the side end of the basalt fiber composite pipe 2 until a distance parameter sensed and detected by one photoelectric probe 401 is larger than the preset pipe end distance of the system.
And step three, polishing and positioning the basalt fiber composite pipe 2
According to the preset polishing propelling depth (polishing depth towards the direction of the basalt fiber composite pipe 2) of the system and the sensing distance distributed among all the photoelectric probes 401 (the photoelectric probes vertically and downwards sense and detect the distance, and a certain distance exists when the adjacent photoelectric probes 401 are designed and installed, the invention does not adopt a CCD-like dense high-precision design, firstly, distance sensing detection is needed, secondly, only a unidirectional (transverse) distribution design is needed in the invention, the requirement on precision is not too high, the precision is too high, the delayed reaction depth of an industrial control system per se cannot be kept up with the requirement, in addition, the design of the invention can reduce the control difficulty to a certain extent and also reduce the cost of devices), the position of the photoelectric probe 401, which is just opposite to the end face of the basalt fiber composite pipe 2 in the vertical direction when polishing is finished, is analyzed and judged, and the photoelectric probe 401 at the position is recorded as a polishing finished photoelectric probe.
Polishing the 2 side end of the basalt fiber composite pipe
And (3) the transverse moving driving device 5 pushes the polishing motor 6 to push towards the basalt fiber composite pipe 2, the sliding sleeve 9 is inserted into the pipe cavity of the basalt fiber composite pipe 2, and when the distance information sensed by the polishing start photoelectric probe in the step (2) is not more than the pipe end distance preset by the system, the polishing motor 6 drives the polishing wheel 7 to rotate to start polishing the side end of the basalt fiber composite pipe 2. When the distance sensed by the photoelectric probe for finishing polishing in the step (3) is a short distance for polishing (the short distance for polishing is the distance when the photoelectric probe senses the polishing wheel 7, such as the distance "S" in fig. 6), polishing is stopped, the traverse driving device 5 drives the polishing motor 6 to return, the sliding sleeve 9 is separated from the basalt fiber composite tube 2, the cylinder assembly 303 drives the clamping plate 305 (such as the position when the clamping plate 305 is close to the cylinder assembly 303 in fig. 5) to return to the initial position, and the support belt transmission 1 continues to forward convey the basalt fiber composite tube 2 after polishing.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.
Claims (8)
1. The utility model provides a directional burnishing device of basalt fiber composite pipe, includes transmission supporting band (1) that is used for directional transmission basalt fiber composite pipe, its characterized in that: the width dimension of the transmission support belt (1) is smaller than the length dimension of the basalt fiber composite pipe, a group of inclined clamping assemblies (3) are arranged at the upper position and the lower position of the side end of the basalt fiber composite pipe, each inclined clamping assembly (3) comprises a directional moving rod (301) and a linear motor (302) slidably mounted on the directional moving rod (301), a cylinder assembly (303) is mounted on the linear motor (302) towards the position of the basalt fiber composite pipe, and each cylinder assembly (303) comprises a propelling shaft rod (304) and a clamping plate (305) mounted at the tail end of the propelling shaft rod (304); all the cylinder assemblies (303) at the same side end position of the basalt fiber composite pipe are connected with the same gas source (12) through a pneumatic pipeline (11), the gas source (12) synchronously transmits gas sources with the same pressure to all the cylinder assemblies (303), and the gas source (12) is provided with a pressure reducing valve (13); a photoelectric distance sensing module (4) is arranged in an area between the two inclined clamping assemblies (3) at the upper side position, and the photoelectric distance sensing module (4) comprises a plurality of photoelectric probes (401) which are arrayed without gaps; the device comprises a transmission supporting belt (1), and is characterized in that transverse movement driving devices (5) are arranged on two side directions of the transmission supporting belt (1), the output side of each transverse movement driving device (5) is connected with a polishing motor (6), the output side of each polishing motor (6) is provided with a rotating shaft rod (601), each rotating shaft rod (601) is connected with a polishing wheel (7) and a bearing sleeve (8) located at the outer side of each polishing wheel (7), a sliding sleeve (9) is fixedly installed on the periphery of each bearing sleeve (8), and the sliding sleeve (9) is inserted into the pipe cavity of the side end of the basalt fiber composite pipe.
2. The basalt fiber composite pipe directional polishing device according to claim 1, wherein: all fixed mounting has one to connect between two oblique position clamping components in upside position (3), two oblique position clamping components in downside position (3) and connects dull and stereotyped (306), linear electric motor (302) with connect dull and stereotyped (306) fixed connection, install the intermediate position of connecting dull and stereotyped (306) in upside position photoelectric distance sensing module (4).
3. The basalt fiber composite pipe directional polishing device according to claim 1, wherein: the distance between the two clamping plates (305) in the same vertical direction at the initial position is larger than the outer diameter size of the basalt fiber composite pipe body.
4. The basalt fiber composite pipe directional polishing device according to claim 1, wherein: the included angle between the two inclined clamping assemblies (3) at the same height position is more than 45 degrees.
5. The basalt fiber composite pipe directional polishing device according to claim 1, wherein: a fixed disc (602) is arranged on the side of the ring of the rotating shaft rod (601), the polishing wheel (7) comprises an inner mounting ring plate (701) and an outer polishing ring plate (702), and the inner mounting ring plate (701) is fixedly connected with the fixed disc (602); wherein the outer diameter of the polishing outer ring plate (702) is larger than that of the basalt fiber composite pipe.
6. The basalt fiber composite pipe directional polishing device according to claim 1, wherein: the bearing sleeve (8) comprises an inner bearing ring and an outer bearing ring, the rotating shaft rod (601) is fixedly connected with the inner bearing ring of the bearing sleeve (8), and the sliding sleeve (9) is fixedly connected with the outer bearing ring of the bearing sleeve (8).
7. The basalt fiber composite pipe directional polishing device according to claim 6, wherein: the side end of the bearing sleeve (8) is provided with a shaft end threaded hole (801), the side end of the sliding sleeve (9) is provided with a threaded through hole (901), and the threaded through hole (901) and the shaft end threaded hole (801) are provided with an axis bolt (10).
8. A basalt fiber composite pipe directional polishing method is characterized in that the basalt fiber composite pipe directional polishing device of any one of claims 1 to 7 is adopted, and the basalt fiber composite pipe directional polishing method comprises the following steps: (1) clamping the end part of the basalt fiber composite pipe: the transmission supporting belt (1) drives the basalt fiber composite pipe to advance, when any one photoelectric probe (401) senses and detects that any one end of the basalt fiber composite pipe enters a vertical sensing detection range of the photoelectric probe (401) and the distance sensed and detected by the photoelectric probe (401) is not more than a preset entering clamping distance of a system, two air cylinder assemblies (303) at the upper side position and two air cylinder assemblies (303) at the lower side position of the current side end simultaneously act to position and clamp the current side end of the basalt fiber composite pipe; any photoelectric probe (401) at the position of the other side end of the basalt fiber composite pipe senses and detects the distance between the basalt fiber composite pipe and the photoelectric probe, the distance is compared with the 'entering clamping distance' for judgment, and the cylinder assembly (303) at the position of the other side end of the basalt fiber composite pipe is used for positioning and clamping the other side end of the basalt fiber composite pipe; (2) side end position finding: a plurality of photoelectric probes (401) of the photoelectric distance sensing module (4) downwards carry out distance detection on the basalt fiber composite tube, the position of a photoelectric probe (401) with the first distance detection larger than the tube end distance preset by the system is analyzed and judged along the direction from the middle part to the side end of the basalt fiber composite tube, and the photoelectric probe (401) at the position is recorded as a polishing starting photoelectric probe; after the two side ends of the basalt fiber composite pipe are positioned and clamped in the step (1), when the side end is searched in the step (2), all photoelectric probes (401) at any side end position of the basalt fiber composite pipe do not sense and detect that the distance is larger than the preset pipe end distance of the system, then the cylinder assembly (303) at the current side end of the basalt fiber composite pipe returns to the initial position, the linear motor (302) drives the photoelectric distance sensing module (4) and the cylinder assembly (303) to translate towards the side end of the basalt fiber composite pipe until a distance parameter sensed and detected by one photoelectric probe (401) is larger than the preset pipe end distance of the system; (3) polishing and positioning: analyzing and judging the position of the photoelectric probe (401) opposite to the basalt fiber composite pipe end surface in the vertical direction when the polishing is finished according to the polishing propelling depth preset by the system and the sensing distance distributed among the photoelectric probes (401), wherein the photoelectric probe (401) at the position is marked as a polishing finished photoelectric probe; (4) polishing the side end of the basalt fiber composite pipe: the transverse moving driving device (5) pushes the polishing motor (6) to push towards the direction of the basalt fiber composite pipe, the sliding sleeve (9) is inserted into a pipe cavity of the basalt fiber composite pipe, and when the distance information sensed by the polishing start photoelectric probe in the step (2) is not larger than the pipe end distance preset by the system, the polishing motor (6) drives the polishing wheel (7) to rotate to start polishing the side end of the basalt fiber composite pipe; and (3) stopping polishing when the distance sensed by the polishing-finished photoelectric probe in the step (3) is a polishing short distance, driving a polishing motor (6) to return by a transverse moving driving device (5), separating a sliding sleeve (9) from the basalt fiber composite pipe, driving a clamping plate (305) to return to an initial position by a cylinder assembly (303), and continuously conveying the polished basalt fiber composite pipe forwards by a transmission supporting belt (1).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202211118799.5A CN115194637B (en) | 2022-09-15 | 2022-09-15 | Directional polishing device and method for basalt fiber composite pipe |
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Cited By (1)
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| CN116922247A (en) * | 2023-09-18 | 2023-10-24 | 四川炬美盛新材料科技有限公司 | Basalt fiber board cutting surface polishing device and method |
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