CN117213410A

CN117213410A - Flatness detection equipment based on panel processing

Info

Publication number: CN117213410A
Application number: CN202311464762.2A
Authority: CN
Inventors: 李显; 刘双方; 李强; 惠孝樊; 刘立博
Original assignee: Heze Ningfeng Wood Industry Co ltd
Current assignee: Heze Ningfeng Wood Industry Co ltd
Priority date: 2023-11-07
Filing date: 2023-11-07
Publication date: 2023-12-12
Anticipated expiration: 2043-11-07
Also published as: CN117213410B

Abstract

The application relates to the technical field of plate flatness detection, and discloses flatness detection equipment based on plate processing, which comprises a detection support arranged obliquely, wherein the detection support comprises a U-shaped frame, strip-shaped slideways are arranged on the inner sides of two sides of the U-shaped frame, a detection assembly is arranged on the lower part of the U-shaped frame in a sliding mode, a movable carrier frame is arranged on the upper position of the inner side of the U-shaped frame in a sliding mode, the movable carrier frame comprises a U-shaped movable frame, first rectangular grooves are formed in the outer sides of two sides of the U-shaped movable frame, second rectangular grooves are formed in the inner sides of two sides of the U-shaped movable frame, two second rectangular grooves are used for inserting plates, and clamping plate units are arranged on two sides of the U-shaped movable frame. The application is matched with two metal shafts arranged on the circular block, clamps the plate to be detected, keeps the plate in a stable state in the detection process, improves the detection accuracy, and can synchronously detect two sides of the plate.

Description

Flatness detection equipment based on panel processing

Technical Field

The application relates to the technical field of plate flatness detection, in particular to flatness detection equipment based on plate processing.

Background

When something is processed or produced, the surface is not perfectly flat, and the difference between the surface and the absolute level is flatness. (the smaller the value, the better). In the furniture industry, flatness refers to the local flatness of the surface of a product (component) within the range of 0-150 mm, the flatness of a plate needs to be detected in the processing process of the plate, the existing detection equipment needs to be matched with a conveyor for use, and the detection efficiency is high, but the equipment is large in size and high in manufacturing cost and is not suitable for introduction of some small factories, so that flatness detection equipment based on plate processing is provided.

Disclosure of Invention

Based on the technical problems in the background technology, the application provides flatness detection equipment based on plate processing.

The application provides flatness detection equipment based on plate processing, which comprises a detection bracket obliquely arranged, wherein the detection bracket comprises a U-shaped frame, strip-shaped slideways are arranged on the inner sides of two sides of the U-shaped frame, a detection assembly is arranged on the lower part of the U-shaped frame in a sliding manner, and a movable carrier is arranged on the upper part of the inner side of the U-shaped frame in a sliding manner;

the movable carrier comprises a U-shaped movable frame, wherein first rectangular grooves are formed in the outer sides of two sides of the U-shaped movable frame, second rectangular grooves are formed in the inner sides of two sides of the U-shaped movable frame, the two second rectangular grooves are used for inserting plates, and clamping plate units are arranged on two sides of the U-shaped movable frame;

the clamping plate unit comprises two clamping components, the inner side of the strip-shaped slideway is provided with circular rotating grooves with the same quantity as the clamping components, the clamping components comprise circular blocks which are arranged in the circular rotating grooves in a rotating mode, two metal shafts which are symmetrically arranged are arranged on one side of each circular block, which is close to the circular rotating grooves, the circular rotating grooves are communicated with a first rectangular groove, gears are coaxially arranged on one side of each circular block, which is far away from the metal shafts, a triggering component which is used for achieving synchronous and reverse rotation of the two gears is arranged in the first rectangular groove, and a steel cable component which moves upwards along with the downward movement of the U-shaped movable frame to achieve upward movement of the detection component is arranged between the U-shaped movable frame and the detection component.

As further optimization of the technical scheme, the flatness detection equipment based on plate processing comprises a rectangular frame sleeved outside a U-shaped frame, rectangular openings are formed in the upper portions of two sides of the rectangular frame, detection units are arranged at positions, close to the rectangular openings, of the two sides of the rectangular frame, each detection unit comprises a rectangular shell fixed on the rectangular frame, rectangular plates are movably arranged in the rectangular shells, guide posts are arranged at the positions of two ends of one side of each rectangular plate, guide holes for the two guide posts to penetrate are formed in the side wall of each rectangular shell, bolt rods are arranged at the middle positions, close to the guide posts, of the side wall of each rectangular shell, through holes for the bolt rods to penetrate are formed in the middle positions, close to the inner sides of the rectangular shells, of the bolt rods, first springs are sleeved on the bolt rods, adjusting caps are screwed on the bolt rods, a strip-shaped mounting frame is arranged on one side, far from the bolt rods, and laser ranging sensors distributed equidistantly are fixed on the strip-shaped mounting frame.

In this preferred scheme, the both sides of here rectangle frame all are provided with detecting element, can follow the both sides of panel and carry out synchronous detection, detect the distance to panel surface through a plurality of laser rangefinder sensors, whether the panel surface is level through the data feedback of distance to cooperate the cable assembly, along with the downmovement of panel, realize detecting assembly and reciprocate, the linkage is effectual, need not extra driving equipment and drives detecting assembly and remove.

As a further optimization of the technical scheme, the flatness detection equipment based on plate processing is characterized in that lifting assemblies are arranged at two ends of the inner side of the rectangular frame, each lifting assembly comprises a movable block which is arranged in a strip-shaped slideway in a sliding mode, two round holes which are arranged along the length direction of the U-shaped frame are formed in the movable block, guide rods are inserted into the two round holes, the lower ends of the two guide rods are fixedly provided with the same trapezoid blocks, the tops of the two guide rods are provided with the same connecting block, and a second spring is sleeved on the outer peripheral surface of the guide rod, close to the position between the connecting block and the movable block.

As a further optimization of the technical scheme, the flatness detection equipment based on plate processing provided by the application has the advantages that a gap is reserved between the plane of the movable block, which is close to the inner side of the U-shaped frame, and the extension plane of the side plane, which is close to the U-shaped movable frame.

As further optimization of the technical scheme, according to the flatness detection equipment based on plate processing, the movable block is provided with the connecting shaft close to the inner side of the strip-shaped slideway, the side wall of the U-shaped frame is provided with the strip-shaped opening for the connecting shaft to slide, and the connecting shaft penetrates through the strip-shaped opening to be fixedly connected with the inner wall of the rectangular frame.

As a further optimization of the technical scheme, the flatness detection equipment based on plate processing comprises a rolling shaft fixed at a gap between the inner side of a strip-shaped slideway and one side of a U-shaped movable frame, wherein a V-shaped pulley is hinged at the middle position of the side wall of the rolling shaft, connecting lugs are arranged at the lower ends of two sides of the U-shaped movable frame, the same steel rope is connected between the connecting lugs and a movable block, and the steel rope bypasses the V-shaped pulley.

In this preferred scheme, here when the in-process that U type adjustable shelf moved down, the pulling cable wire, the V type pulley of cooperation setting, pulling movable block moves up to drive the detection component and move up together, the panel that sets up in U type adjustable shelf can meet with the detection component that moves up, can carry out the detection of face roughness.

As a further optimization of the technical scheme, the trigger component comprises a movable frame which is arranged at the lower part of the inner side of a first rectangular groove in a sliding manner, the lower end of the first rectangular groove is of an opening structure through which the movable frame can pass, two symmetrically arranged metal rods are fixedly arranged at the upper part of the movable frame, a first rack is fixedly arranged on one metal rod, the first rack is meshed with a gear positioned at the lower part, a shaft pin is arranged at the position, close to the position between two clamping components, of the inner side of the first rectangular groove, an outer toothed ring is rotatably arranged on the shaft pin, the outer toothed ring is meshed with the first rack, a second rack is sleeved on the other metal rod, the second rack is meshed with the outer toothed ring, an L-shaped connecting rod is arranged at the top of the second rack, a third rack is fixedly arranged on the L-shaped connecting rod and meshed with a gear positioned at the upper part, and the third rack is inserted into one metal rod provided with the first rack.

As a further optimization of the technical scheme, the flatness detection equipment based on plate processing is characterized in that the width of the trapezoid block is larger than that of the movable block, and the trapezoid block corresponds to the position of the movable frame.

In the preferred scheme, when the U-shaped movable frame carrying the plate moves down and pulls the steel cable, the detection assembly is driven to move upwards, after the movable frame is contacted with the corresponding trapezoid block, the movable frame is driven to move in the first rectangular groove continuously in the process of moving down, the first rack is pushed to move in the process of moving upwards, the gear positioned at the lower part is driven to rotate anticlockwise in the process of moving upwards, the two metal shafts matched with the movable frame are used for clamping the plate, the second rack is driven to move downwards, the L-shaped connecting rod and the third rack are driven to move by the second rack which moves downwards, the gear positioned at the upper part is driven to rotate clockwise by the third rack which is arranged, the two metal shafts positioned at the upper part are driven to rotate by a certain angle, the plate is clamped, the plate is kept in a stable state in the detection process, the trapezoid block is blocked by the movable frame continuously moving downwards, the steel cable drives the movable block and the rectangular frame to move upwards continuously, and the detection unit plate surface is driven to detect.

As a further optimization of the technical scheme, the flatness detection equipment based on plate processing is characterized in that a display assembly is arranged at the top of the side wall of the U-shaped frame and comprises a display bracket fixed at the top of the side wall of the U-shaped frame, a display screen is fixedly arranged on the upper portion of the display bracket, the display screen is connected with a microprocessor, and the microprocessor is connected with a laser ranging sensor.

As further optimization of the technical scheme, the flatness detection equipment based on plate processing is characterized in that two ends of the upper portion of the U-shaped frame extend outwards to form bending portions.

In summary, the beneficial effects of the application are as follows:

through the U type adjustable shelf that sets up, the trigger subassembly that the cooperation set up, can cooperate with trapezoidal piece, in-process when trigger subassembly shifts up can realize being located two clamping components of U type adjustable shelf with one side and realize the rotation of opposite direction, two metal shafts of cooperation setting on circular piece, it presss from both sides tightly to treat the sheet material, keep the sheet material detection in-process to be in steady state, promote the accuracy that detects, pull up the sheet material simultaneously, detection component resets under the action of gravity, after the adjustable shelf no longer atress, the sheet material can be taken out from two metal shafts on the clamping components, conveniently get and put the sheet material, and easy operation, high efficiency is convenient, two sets of detecting element that the cooperation set up can carry out synchronous detection to the both sides of sheet material, the equipment is small, the cost is low, easily popularization.

Drawings

Fig. 1 is a schematic structural diagram of a flatness detecting device based on board processing according to the present application;

fig. 2 is a schematic structural diagram of a flatness detecting device display assembly based on board processing according to the present application;

FIG. 3 is a schematic view of a flatness detection apparatus based on sheet processing according to the present application, with the bracket and display assembly removed;

FIG. 4 is a schematic structural view of a flatness detecting device detecting assembly and a steel cable assembly based on sheet processing according to the present application;

fig. 5 is a schematic structural view of a rectangular frame of a flatness detecting device based on board processing according to the present application;

FIG. 6 is a schematic diagram of an explosion structure of a detecting unit of a flatness detecting device based on sheet processing according to the present application;

FIG. 7 is a schematic view of a movable carrier and cable assembly of a flatness detection apparatus based on sheet material processing according to the present application;

fig. 8 is a schematic structural view of a U-shaped movable frame of a flatness detecting device based on board processing according to the present application;

fig. 9 is a schematic structural diagram of a trigger assembly of a flatness detecting device based on board processing according to the present application;

fig. 10 is a schematic structural diagram of a clamping assembly of a flatness detecting device based on board processing according to the present application.

In the figure: 1. a bracket; 2. a detection assembly; 201. a rectangular frame; 2011. rectangular openings; 202. a detection unit; 2021. a rectangular housing; 2022. a bolt rod; 2023. a rectangular plate; 2024. a strip-shaped mounting rack; 2025. a laser ranging sensor; 2026. a first spring; 2027. an adjustment cap; 203. a lifting assembly; 2031. a movable block; 2032. a trapezoid block; 2033. a guide rod; 2034. a connecting block; 2035. a second spring; 3. detecting a bracket; 301. a U-shaped frame; 3011. a strip-shaped slideway; 3012. a strip-shaped notch; 3013. a bending part; 4. a display assembly; 401. a display stand; 402. a display screen; 5. a movable carrier; 501. a U-shaped movable frame; 5011. a first rectangular groove; 50111. a shaft pin; 5012. a second rectangular groove; 5013. a circular rotating groove; 5014. a connecting lug; 502. a clamping assembly; 5021. a circular block; 5022. a gear; 5023. a metal shaft; 503. a trigger assembly; 5031. a movable frame; 5032. a metal rod; 5033. a first rack; 5034. a second rack; 5035. an outer toothed ring; 5036. a third rack; 6. a wire rope assembly; 601. a wire rope; 602. a roller; 603. v-shaped pulley.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to fig. 1 to 10 in the embodiments of the present application, and it is obvious that the described embodiments are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Referring to fig. 1-10, a flatness detection device based on board processing comprises a detection bracket 3 which is obliquely arranged, wherein the detection bracket 3 comprises a U-shaped frame 301, strip-shaped slide ways 3011 are arranged on the inner sides of two sides of the U-shaped frame 301, a detection assembly 2 is slidably arranged on the lower part of the U-shaped frame 301, and a movable carrier 5 is slidably arranged on the upper part of the inner side of the U-shaped frame 301;

the movable carrier 5 comprises a U-shaped movable frame 501, wherein first rectangular grooves 5011 are formed in the outer sides of two sides of the U-shaped movable frame 501, second rectangular grooves 5012 are formed in the inner sides of two sides of the U-shaped movable frame 501, the two second rectangular grooves 5012 are used for inserting plates, and clamping plate units are arranged on two sides of the U-shaped movable frame 501;

the clamping plate unit comprises two clamping components 502, circular rotating grooves 5013 consistent with the clamping components 502 in quantity are formed in the inner side of the strip-shaped slide 3011, the clamping components 502 comprise circular blocks 5021 which are arranged in the circular rotating grooves 5013 in a rotating mode, two metal shafts 5023 which are symmetrically arranged are arranged on one side, close to the circular rotating grooves 5013, of each circular block 5021, the circular rotating grooves 5013 are communicated with a first rectangular groove 5011, gears 5022 are coaxially arranged on one side, away from the metal shafts 5023, of each circular block 5021, a trigger component 503 which is used for achieving synchronous reverse rotation of the two gears 5022 is arranged in each first rectangular groove 5011, and a steel cable component 6 which moves upwards along with the downward movement of the U-shaped movable frame 501 to achieve upward movement of the detection component 2 is arranged between the U-shaped movable frame 501 and the detection component 2.

Referring to fig. 4, fig. 5 and fig. 6, the detection component 2 is including the cover establishes the rectangle frame 201 in the U type frame 301 outside, rectangle frame 201 both sides upper portion all is provided with rectangle breach 2011, rectangle frame 201 both sides are close to rectangle breach 2011 position department and are provided with detection unit 202, detection unit 202 includes the rectangle casing 2021 of fixing on rectangle frame 201, the activity is provided with rectangular plate 2023 in the rectangle casing 2021, rectangular plate 2023 one side both ends position department all is provided with the guide post, rectangular plate 2021 lateral wall is provided with the guiding hole that supplies two guide posts to pass, rectangular plate 2023 is close to guide post one side intermediate position department and is provided with bolt bar 2022, rectangular plate 2021 lateral wall intermediate position department is provided with the through-hole that supplies bolt bar 2022 to pass, bolt bar 2022 is close to rectangular plate 2021 inboard position department and overlaps and is equipped with first spring 2026, the spiro union has regulation cap 2027 on the bolt bar 2022, rectangular plate 2023 is kept away from bolt 2022 one side 2024, the distance measuring device 2024 is provided with the sensor to the distance measuring device is moved to the distance measuring device with the sensor along with the square plate material, and the distance measuring device is detected to the distance measuring device is realized to the distance measuring device, and the distance measuring device is moved to the both sides along with the distance measuring device is equipped with the distance measuring device to the laser, and is detected to the distance measuring device is equipped with the distance measuring device to the distance measuring device is measured to the distance measuring device.

Referring to fig. 4, fig. 5 and fig. 6, the two ends of the inner side of the rectangular frame 201 are respectively provided with a lifting assembly 203, the lifting assembly 203 comprises a movable block 2031 slidably arranged in a strip-shaped slide 3011, two round holes are formed in the movable block 2031 and are arranged along the length direction of the U-shaped frame 301, guide rods 2033 are respectively inserted into the two round holes, the same trapezoid block 2032 is fixed at the lower end of the guide rods 2033, the same connecting block 2034 is arranged at the top of the guide rods 2033, a second spring 2035 is sleeved at the position, between the connecting block 2034 and the movable block 2031, of the outer peripheral surface of the guide rods 2033, a gap is reserved between the plane, close to the inner side of the U-shaped frame 301, of the movable block 2031 and the extension plane, close to the side plane of the U-shaped movable frame 501, a connecting shaft is arranged on the inner side of the movable block 2031, the side wall of the U-shaped frame 301 is provided with a notch 3012 for sliding the connecting shaft, and the connecting shaft penetrates through the notch 3012 to be fixedly connected with the strip-shaped frame 301201.

Referring to fig. 3, fig. 4 and fig. 7, the steel cable assembly 6 includes a roller 602 fixed at a gap between the inner side of the strip-shaped slide 3011 and one side of the U-shaped movable frame 501, a V-shaped pulley 603 is hinged at a middle position of a side wall of the roller 602, connecting lugs 5014 are respectively disposed at lower ends of two sides of the U-shaped movable frame 501, a same steel cable 601 is connected between the connecting lugs 5014 and the movable blocks 2031, the steel cable 601 bypasses the V-shaped pulley 603, and when the U-shaped movable frame 501 moves downwards, the steel cable 601 is pulled, the V-shaped pulley 603 is cooperated with the movable blocks 2031 to move upwards, so as to drive the detection assembly 2 to move upwards together, and a plate disposed on the inner side of the U-shaped movable frame 501 meets the detection assembly 2, so that the flatness of the plate surface can be detected.

Referring to fig. 7, 8 and 9, the triggering component 503 includes a movable frame 5031 slidably disposed at a lower portion of an inner side of a first rectangular slot 5011, an opening structure through which the movable frame 5031 passes is formed at a lower end of the first rectangular slot 5011, two symmetrically disposed metal rods 5032 are fixedly disposed at an upper portion of the movable frame 5031, a first rack 5033 is fixedly disposed on one of the metal rods 5032, the first rack 5033 is engaged with a gear 5022 disposed at a lower portion, a shaft pin 50111 is disposed at a position between the two clamping components 502 and adjacent to the inner side of the first rectangular slot 5011, an external gear ring 5035 is rotatably disposed on the shaft pin 50111, the external gear ring 5035 is engaged with the first rack 5033, a second rack 5034 is sleeved on the other metal rod 5032, the second rack 5034 is engaged with the external gear ring 5035, an L-shaped connecting rod is disposed at a top of the second rack 5034, a third rack 5036 is fixedly disposed on the L-shaped connecting rod, the third rack 5036 is meshed with the gear 5022 at the upper part, the third rack 5036 is inserted on one metal rod 5032 provided with the first rack 5033, the width of the trapezoid block 2032 is larger than that of the movable block 2031, the trapezoid block 2032 corresponds to the movable frame 5031 in position, when the U-shaped movable frame 501 carrying a plate moves down, the steel cable 601 is pulled to drive the detection assembly 2 to move up, when the movable frame 5031 contacts with the corresponding trapezoid block 2032, the movable frame 5031 is driven to move in the first rectangular groove 5011 in the process of moving down, the first rack 5033 is driven to move in the process of moving up, the gear 5022 at the lower part is driven to rotate anticlockwise, the two metal shafts 5023 matched with each other clamp the plate, and the outer gear ring 5035 matched with each other drives the second rack 5034 to move down, the second rack 5034 moving downwards pulls the L-shaped connecting rod and the third rack 5036 to move, so that the third rack 5036 drives the gear 5022 on the upper part to rotate clockwise, drives the two metal shafts 5023 on the upper part to rotate by a certain angle, clamps the plate, keeps the plate in a stable state in the detection process, and as the U-shaped movable frame 501 moves downwards continuously, the trapezoid block 2032 is blocked by the movable frame 5031, the steel cable 601 drives the movable block 2031 and the rectangular frame 201 to move upwards continuously, and drives the detection unit 202 to detect the plate surface of the plate.

Referring to fig. 1 and 2, a display assembly 4 is disposed at a top position of a side wall of the U-shaped frame 301, the display assembly 4 includes a display bracket 401 fixed at the top position of the side wall of the U-shaped frame 301, and a display screen 402 is fixedly disposed on an upper portion of the display bracket 401, the display screen 402 is connected with a microprocessor, and the microprocessor is connected with a laser ranging sensor 2025.

Referring to fig. 3, the U-shaped frame 301 has two ends extending outwards to form a bending portion 3013.

Working principle: when in use, a plate to be tested is inserted into the inner side of the U-shaped movable frame 501 along the two second rectangular grooves 5012, and passes through the two metal shafts 5023 in the corresponding clamping assembly 502, and then is communicated with the plate and the U-shaped movable frame 501 to move downwards together, when the movable frame 5031 contacts with the trapezoidal block 2032 at the corresponding side, the movable frame 5031 and the U-shaped movable frame 501 are relatively displaced, the upward-moving first rack 5033 drives the gear 5022 positioned below to rotate anticlockwise, drives the corresponding two metal shafts 5023 to rotate, then drives the second rack 5034 to move downwards in cooperation with the external gear ring 5035, thereby driving the corresponding gear 5022 to rotate clockwise, thereby driving the corresponding two metal shafts 5023 to rotate, clamping the plate to be tested, continuing to move downwards, the steel cable 601 pulls the movable block 2031 and the rectangular frame 201 to move upwards together, the second spring 2035 on the guide rod 2033 is compressed in the upward movement process, after the detection component 2 meets the plate, the two sides of the plate are detected by the detection units 202 on the two sides, the distance between the plate and the plate surface is detected by the plurality of laser ranging sensors 2025, the specific detection process is that the plurality of laser ranging sensors 2025 detect the distance data of the plate surface to be detected, whether the plate is flat or not is reflected according to the difference value between the data, a difference value threshold is set, when the difference value is larger than the threshold, the plate does not meet the flatness requirement, the position of the plate 2023 in the rectangular shell 2021 can be adjusted by the adjusting cap 2027 on the bolt rod 2022, the distance between the laser ranging sensors 2025 and the plate surface to be detected can be adjusted, and the plate materials with different thicknesses can be adjusted in an adaptive manner.

Spatially relative terms, such as "above … …," "above … …," "upper surface at … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial location relative to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "above" or "over" other devices or structures would then be oriented "below" or "beneath" the other devices or structures. Thus, the exemplary term "above … …" may include both orientations of "above … …" and "below … …". The device may also be positioned in other different ways (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present application. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present application and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that embodiments of the application described herein may be capable of being practiced otherwise than as specifically illustrated and described. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing is only a preferred embodiment of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art, who is within the scope of the present application, should make equivalent substitutions or modifications according to the technical scheme of the present application and the inventive concept thereof, and should be covered by the scope of the present application.

Claims

1. The flatness detection device based on plate processing comprises a detection support (3) which is obliquely arranged, and is characterized in that the detection support (3) comprises a U-shaped frame (301), strip-shaped slide ways (3011) are arranged on the inner sides of two sides of the U-shaped frame (301), a detection assembly (2) is arranged on the lower portion of the U-shaped frame (301) in a sliding mode, and a movable carrier frame (5) is arranged on the upper portion of the inner side of the U-shaped frame (301) in a sliding mode;

the movable carrier plate frame (5) comprises a U-shaped movable frame (501), wherein first rectangular grooves (5011) are formed in the outer sides of two sides of the U-shaped movable frame (501), second rectangular grooves (5012) are formed in the inner sides of two sides of the U-shaped movable frame (501), the two second rectangular grooves (5012) are used for inserting plates, and clamping plate units are arranged on two sides of the U-shaped movable frame (501);

the clamping plate unit comprises two clamping components (502), circular rotating grooves (5013) with the same quantity as the clamping components (502) are formed in the inner side of the strip-shaped slide way (3011), the clamping components (502) comprise circular blocks (5021) which are arranged in the circular rotating grooves (5013) in a rotating mode, the circular blocks (5021) are close to two metal shafts (5023) which are symmetrically arranged on one side of the circular rotating grooves (5013), the circular rotating grooves (5013) are communicated with a first rectangular groove (5011), gears (5022) are coaxially arranged on one side, away from the metal shafts (5023), of the circular blocks (5021), trigger components (503) which are used for achieving synchronous and reverse rotation of the two gears (5022) are arranged in the first rectangular groove (5011), and steel cable components (6) which move upwards along with the U-shaped movable frames (501) move downwards to achieve the detection components (2) are arranged between the U-shaped movable frames (501).

2. The flatness detection apparatus based on sheet processing according to claim 1, wherein the detection assembly (2) comprises a rectangular frame (201) sleeved outside the U-shaped frame (301), rectangular openings (2011) are formed in the upper portions of two sides of the rectangular frame (201), detection units (202) are arranged at positions, close to the rectangular openings (2011), of two sides of the rectangular frame (201), the detection units (202) comprise rectangular shells (2021) fixed to the rectangular frame (201), rectangular plates (2023) are movably arranged in the rectangular shells (2021), guide posts are arranged at positions of two ends on one side of the rectangular plates (2023), guide holes for the two guide posts to penetrate through are formed in the side walls of the rectangular shells (2021), bolt rods (2022) are arranged at positions, close to the middle positions of one sides of the guide posts, of the rectangular shells (2023), through holes for the bolt rods (2022) to penetrate through, the inner side walls (2022) of the rectangular shells (2021) are provided with guide holes for the bolt rods (2022), the bolt rods (2022) to penetrate through, the first screw caps (2026) are arranged at positions, close to the inner side walls (2022) of the rectangular shells (2021), the first screw caps (2026) are far from the first screw caps (2024), and laser ranging sensors (2025) distributed at equal intervals are fixed on the strip-shaped mounting frame (2024).

3. The flatness detection equipment based on plate processing according to claim 2, characterized in that lifting components (203) are arranged at two ends of the inner side of the rectangular frame (201), the lifting components (203) comprise movable blocks (2031) which are arranged in the strip-shaped slide ways (3011) in a sliding mode, two round holes which are arranged along the length direction of the U-shaped frame (301) are formed in the movable blocks (2031), guide rods (2033) are inserted into the two round holes, the lower ends of the two guide rods (2033) are fixedly provided with the same trapezoid block (2032), the tops of the two guide rods (2033) are provided with the same connecting block (2034), and a second spring (2035) is sleeved at the position, between the connecting block (2034) and the movable block (2031), of the outer peripheral surface of the guide rod (2033).

4. A flatness detecting apparatus based on sheet processing according to claim 3, characterized in that a gap is left between a plane of the movable block (2031) near the inside of the U-shaped frame (301) and an extension plane of a side plane of the U-shaped movable frame (501) near.

5. The flatness detection apparatus based on board processing according to claim 3, wherein a connection shaft is provided on one side of the movable block (2031) close to the inner side of the strip-shaped slide way (3011), a strip-shaped opening (3012) for sliding the connection shaft is provided on the side wall of the U-shaped frame (301), and the connection shaft passes through the strip-shaped opening (3012) and is fixedly connected with the inner wall of the rectangular frame (201).

6. The flatness detection apparatus based on board processing according to claim 5, wherein the steel cable assembly (6) comprises a roller (602) fixed at a gap between the inner side of the strip-shaped slide way (3011) and one side of the U-shaped movable frame (501), a V-shaped pulley (603) is hinged at the middle position of the side wall of the roller (602), connecting lugs (5014) are arranged at the lower ends of two sides of the U-shaped movable frame (501), the same steel cable (601) is connected between the connecting lugs (5014) and the movable blocks (2031), and the steel cable (601) bypasses the V-shaped pulley (603).

7. The flatness detection apparatus based on sheet processing of claim 6, wherein the trigger assembly (503) comprises a movable frame (5031) slidably disposed at a lower portion inside the first rectangular groove (5011), an opening structure through which the movable frame (5031) passes is provided at a lower end of the first rectangular groove (5011), two symmetrically disposed metal rods (5032) are fixedly disposed at an upper portion of the movable frame (5031), a first rack (5033) is fixedly disposed on one of the metal rods (5032), the first rack (5033) is meshed with a gear (5022) disposed at a lower portion, a shaft pin (50111) is disposed at a position between two clamping assemblies (502) inside the first rectangular groove (5011), an outer toothed ring (5035) is rotatably disposed on the shaft pin (50111), the outer toothed ring (5035) is meshed with the first rack (5033), a second rack (5034) is fixedly disposed on the upper portion of the metal rod (5032), the second rack (5034) is meshed with a third rack (5036) and a third rack (5036) is disposed on a top portion of the third rack (5036).

8. The flatness detection apparatus based on sheet processing of claim 7, wherein the width of the trapezoid block (2032) is larger than the width of the movable block (2031), the trapezoid block (2032) corresponding to the position of the movable frame (5031).

9. The flatness detection apparatus based on sheet processing according to claim 7, characterized in that the display assembly (4) is provided at a position of a top of a side wall of the U-shaped frame (301), the display assembly (4) includes a display bracket (401) fixed at a position of a top of a side wall of the U-shaped frame (301), and a display screen (402) is fixedly provided at an upper portion of the display bracket (401), the display screen (402) is connected with a microprocessor, and the microprocessor is connected with a laser ranging sensor (2025).

10. The flatness detection apparatus based on sheet processing of claim 7, wherein both ends of the upper portion of the U-shaped frame (301) are extended outwardly to form bent portions (3013).