CN211163257U - Positioning auxiliary device of energy-saving building stone edge grinding machine - Google Patents

Abstract

The utility model discloses an energy-saving building stone material edging machine's location auxiliary device, including the bottom plate that is used for placing the stone flitch, be provided with the fixed block that is used for fixed stone flitch on the bottom plate, the fixed block includes first U type piece and second U type piece, first U type piece runs through and has seted up first U type groove, first U type inslot is provided with and is used for realizing first U type piece with wobbling locating component takes place for second U type piece, second U type piece runs through and has seted up second U type groove, second U type inslot is provided with and is used for the drive second U type piece wobbling drive assembly. Through above-mentioned technical scheme, second U type piece upswing drives first U type piece downswing to with the stone flitch butt, realize compressing tightly the effect of fixed stone flitch.

Description

Positioning auxiliary device of energy-saving building stone edge grinding machine

Technical Field

The utility model belongs to the technical field of the technique of stone material processing equipment and specifically relates to a location auxiliary device of energy-saving building stone material edging machine is related to.

Background

In the process of processing the stone plate, the stone plate needs to be cut and subjected to plane grinding to reach the size required by a customer, and the cut stone has cut marks on the side surface, so that the appearance is influenced, microcracks are easily caused in the using process, and the subsequent use is influenced, therefore, the stone needs to be subjected to chamfering treatment after being cut, or edge breakage is easily caused in the subsequent operation process; the existing part adopts manual edge grinding and chamfering for the stone, so that the working efficiency is low, the labor intensity is high, and the quality is unstable; the part adopts the edging machine to polish, need the position of polishing with the stone flitch to place in the edging machine position, and the bistrique of edging machine rotates and polishes the stone flitch, nevertheless because bistrique rigidity leads to the edging operation inconvenient.

In order to solve the problems, the Chinese patent with the publication number of CN209551369U provides a small stone edge grinding machine with adjustable angle, which comprises a platform bracket, a grinding head motor, a slide block and a transmission screw rod, a collecting tank is arranged at the upper part of the platform bracket, a workbench is arranged in the collecting tank, two rocker arms which are symmetrically arranged are arranged at two sides of the platform bracket, the lower part of each rocker arm is respectively and fixedly connected with the two side parts of the platform bracket, one side of the upper part of each rocker arm is provided with a telescopic supporting rod body, two guide rods are fixedly arranged between the two rocker arms, the slide block is slidably arranged on the two guide rods, one end of the transmission screw rod penetrates out of one side of the rocker arm and is connected with a driving motor, a rotating shaft of the grinding head motor is fixedly connected with a grinding head grinding wheel, a protective cover is sleeved outside the grinding head grinding wheel, and a water spraying gun head is arranged on the protective cover.

The above prior art solutions have the following drawbacks: the stone edge grinding machine processes the stone through the angle of removing the bistrique and adjusting the bistrique, but the stone is arranged in and is driven by the bistrique that removes easily on the platform support, leads to the stone position to take place the skew, influences the effect of cutting.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an energy-saving building stone material edging machine's location auxiliary device, it has the effect of the rigidity of guaranteeing the stone flitch.

The utility model discloses a can realize through following technical scheme:

the utility model provides an energy-saving building stone material edging machine's location auxiliary device, is including the bottom plate that is used for placing the stone flitch, be provided with the fixed block that is used for fixed stone flitch on the bottom plate, the fixed block includes first U type piece and second U type piece, first U type piece runs through and has seted up first U type groove, first U type inslot is provided with and is used for realizing first U type piece with second U type piece takes place wobbling locating component, second U type piece runs through and has seted up second U type groove, second U type inslot is provided with and is used for the drive second U type piece wobbling drive assembly.

Through adopting above-mentioned technical scheme, place the stone flitch in first U type piece below, under drive assembly's effect, the second U type piece of upwards swinging, the first U type piece of second U type piece drive swings up, first U type piece swing to with locating component butt, locating component restriction first U type piece upward movement, the position of first U type piece and locating component butt becomes first U type piece and second U type piece wobbling fulcrum, second U type piece up-swing makes first U type piece swing down around the fulcrum to with the stone flitch butt, realize the fixed effect of compressing tightly of first U type piece to the stone flitch.

Further setting the following steps: the positioning assembly comprises a positioning stud slidably connected to the bottom plate and a positioning nut in threaded connection with the positioning stud, and a gap used for swinging of the first U-shaped block is reserved between the positioning stud and the bottom wall of the first U-shaped groove.

Through adopting above-mentioned technical scheme, when fixed stone flitch, set nut moves to the position that is close to first U type piece on the set stud, and second U type piece drives first U type piece and swings up to first U type piece and set nut butt, and first U type piece and set stud butt, and set stud and set nut realize the effect of the upward movement of first U type piece of restriction, provide the fulcrum for the swing of first U type piece and second U type piece.

Further setting the following steps: and the second U-shaped block is abutted against the lower bottom surface of the positioning nut when the first U-shaped block swings to extrude and clamp the stone plate.

Through adopting above-mentioned technical scheme, first U type piece swings to the butt with set nut, and positioning stud restriction set nut and first U type piece upward movement, and the position of first U type piece and set nut butt becomes the first U type piece and the wobbling fulcrum of second U type piece.

Further setting the following steps: the first U-shaped block is provided with a groove used for providing a swing space of the first U-shaped block on the inner wall of the bottom end of the first U-shaped groove.

Through adopting above-mentioned technical scheme, the recess provides the space that is used for first U type piece wobbling for between the diapire in positioning stud and first U type groove for first U type piece is in recess department and positioning stud butt when upwards swinging.

Further setting the following steps: the drive assembly include the level place drive block and sliding connection in the backing plate of bottom plate, the drive block is oval cylindricality, the drive block with second U type piece articulates there is the oscillating axle, the axis of oscillating axle passes the central point of the both sides of drive block, the major axis motion of the vertical elliptic cross section of drive block is to the butt during the backing plate first U type piece orientation downward swing to with the stone flitch butt.

By adopting the technical scheme, the driving block rotates around the swinging shaft along the circumferential direction, and the contact point of the driving block and the base plate gradually rotates from the end point of the semishort shaft to the end point of the semilong shaft, so that the height of the swinging shaft gradually rises, and the effect of upward movement of the second U-shaped block is realized.

Further setting the following steps: the driving block is fixedly connected with a driving rod, and the axis of the driving rod is overlapped with the short axis of the vertical elliptical section of the driving block.

Through adopting above-mentioned technical scheme, when the actuating lever swung down to the horizontal department, the actuating lever made the actuating block drive second U type piece and swung up to the peak, and the actuating lever is in horizontal position and avoids influencing the work of stone grinder.

Further setting the following steps: the bottom plate is provided with a T-shaped sliding groove used for the positioning stud to slide, the bottom plate is provided with openings at two ends of the sliding groove in the horizontal direction, and the positioning stud is fixedly connected with a T-shaped first sliding strip sliding in the sliding groove.

Through adopting above-mentioned technical scheme, first draw runner restriction positioning stud removes along vertical direction in the spout, and positioning stud restriction set nut and first U type piece upward movement realize being convenient for first U type piece around the butt department with positioning nut swing downwards to the effect with the stone flitch butt.

Further setting the following steps: the backing plate is fixedly connected with a second slide bar of the cuboid, which slides in the sliding groove.

Through adopting above-mentioned technical scheme, the backing plate slides to between bottom plate and the driving block along the spout, and the backing plate increases the height of driving block, and first U type piece is swung downwards to the butt with the stone slab when guaranteeing the major axis motion of the vertical elliptic cross-section of driving block to the butt backing plate.

Further setting the following steps: and one side of the second U-shaped block, which is close to the stone plate, is fixedly connected with a rubber sheet.

Through adopting above-mentioned technical scheme, the sheet rubber is located between first U type piece and the stone flitch, and when first U type piece compressed tightly the stone flitch, the pressure of first U type piece was cushioned to the sheet rubber, realizes preventing the effect that first U type piece damaged the stone flitch.

To sum up, the utility model discloses a beneficial technological effect does:

(1) the driving rod drives the driving block to rotate downwards along the circumferential direction, the contact point of the driving block and the base plate gradually rotates from the end point of the semishort shaft to the end point of the semilong shaft, the long shaft of the vertical elliptic section of the driving block moves to be abutted to the base plate, and the second U-shaped block moves upwards to the highest point, so that the effect of driving the second U-shaped block to move upwards is achieved.

(2) The second U-shaped block drives the first U-shaped block to swing upwards to the first U-shaped block to abut against the positioning nut, the position of the first U-shaped block abutting against the positioning nut becomes a fulcrum of the first U-shaped block and the second U-shaped block, the second U-shaped block swings upwards to enable the first U-shaped block to swing downwards around the fulcrum to abut against the stone plate, and the effect of the first U-shaped block on compressing and fixing the stone plate is achieved.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is an enlarged view at A in FIG. 1;

fig. 3 is an exploded view of the first U-shaped block and the positioning stud of the present invention.

Reference numerals: 1. a base plate; 2. a fixed block; 3. a first U-shaped block; 4. a second U-shaped block; 5. a first U-shaped groove; 6. positioning the stud; 7. positioning a nut; 8. a groove; 9. a second U-shaped groove; 10. a drive block; 11. a drive rod; 12. a swing shaft; 13. a base plate; 14. a chute; 15. a first slide bar; 16. a second slide bar; 17. a rubber sheet.

Detailed Description

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

Referring to fig. 1 and 3, for the utility model discloses an energy-saving building stone material edging machine's location auxiliary device, including the bottom plate 1 that is used for placing the stone flitch, be provided with fixed block 2 that is used for fixed stone flitch on the bottom plate 1, fixed block 2 includes first U type piece 3 and second U type piece 4, first U type piece 3 runs through and has seted up first U type groove 5, be provided with in first U type groove 5 and be used for realizing that first U type piece 3 and second U type piece 4 take place wobbling locating component, locating component includes sliding connection in bottom plate 1's locating stud 6 and with locating stud 6 threaded connection's set nut 7, locating stud 6 and bottom plate 1 sliding connection just are fixed in on bottom plate 1 in vertical direction, first U type piece 3 offers the recess 8 that is used for providing first U type piece 3 swing space in first U type groove 5 bottom inner wall.

Referring to fig. 1 and 3, when the stone slab is fixed, the positioning nut 7 moves on the positioning stud 6 to a position close to the first U-shaped block 3, the second U-shaped block 4 swings upwards, the position, abutted to the positioning nut 7, of the first U-shaped block 3 becomes a pivot of the first U-shaped block 3 and the second U-shaped block 4, the second U-shaped block 4 drives the first U-shaped block 3 to swing upwards around the position of the positioning stud 6, the first U-shaped block 3 swings to be abutted to the positioning nut 7, the first U-shaped block 3 abuts to the positioning stud 6 in the groove 8, the positioning stud 6 limits the positioning nut 7 and the first U-shaped block 3 to move upwards, and the second U-shaped block 4 swings upwards to enable the first U-shaped block 3 to swing downwards to be abutted to the stone slab around the pivot, so that the first U-shaped block 3 compresses and fixes the stone slab.

Referring to fig. 1 and 2, in order to conveniently drive the first U-shaped block 3 to compress the stone slab, the second U-shaped block 4 is provided with a second U-shaped groove 9 in a penetrating manner, a driving assembly for driving the second U-shaped block 4 to swing is arranged in the second U-shaped groove 9, the driving assembly comprises a driving block 10 and a driving rod 11 which are horizontally arranged, the driving block 10 is in an elliptic cylinder shape, the driving block 10 and the second U-shaped block 4 are hinged to form a swinging shaft 12 and a backing plate 13, the axis of the swinging shaft 12 penetrates through the central points of two sides of the driving block 10, the driving rod 11 and one side of the driving block 10, which is far away from the bottom plate, and the axis of the driving rod 11 coincides with the short axis of the vertical elliptical section of the driving block 10, the backing plate 13 is connected between the second U-shaped block 4 and the bottom plate 1 in a sliding manner, and the first U-shaped block 3 swings downwards to abut against the stone plate when the long axis of the vertical elliptical section of the driving block 10 moves to abut against the backing plate 13.

Referring to fig. 1 and 2, the driving rod 11 is swung downwards, the driving rod 11 drives the driving block 10 to rotate along the circumferential direction, and the contact point between the driving block 10 and the cushion plate 13 gradually rotates from the end point of the semi-short axis to the end point of the semi-long axis, so that the height of the swing shaft 12 gradually rises, and the effect of driving the second U-shaped block 4 to move upwards is achieved; when the driving rod 11 moves to the axis direction and is parallel to the length direction of the bottom plate 1, the long axis of the vertical elliptical cross section of the driving block 10 moves to the abutting base plate 13, the second U-shaped block 4 moves upwards to the highest point, the second U-shaped block 4 drives the first U-shaped block 3 to swing upwards to abut against the first U-shaped block 3 and the positioning nut 7, the first U-shaped block 3 swings downwards around the abutting position of the positioning nut 7 to abut against the stone plate, and the effect that the first U-shaped block 3 compresses the stone plate is achieved.

Referring to fig. 1 and 2, in order to facilitate the sliding of the positioning stud 6 and the backing plate 13, a T-shaped sliding groove 14 is formed in the bottom plate 1 in a penetrating manner along the length direction, the positioning stud 6 is fixedly connected with a first sliding strip 15 which slides in the sliding groove 14, the first sliding strip 15 is T-shaped, the backing plate 13 is fixedly connected with a second sliding strip 16 which slides in the sliding groove 14, and the second sliding strip 16 is cuboid; in order to improve the compressing effect of the first U-shaped block 3 and the stone plate, one side of the first U-shaped block 3, which is close to the stone plate, is fixedly connected with a rubber sheet 17.

Referring to fig. 1 and 2, before the stone plate is fixed, the positioning stud 6 is moved to abut against the stone plate along the sliding groove 14, the backing plate 13 is moved to the position below the driving block 10 along the sliding groove 14, the second U-shaped block 4 swings upwards to drive the first U-shaped block 3 to swing upwards to abut against the positioning nut 7, the first slide bar 15 limits the positioning stud 6 to move in the sliding groove 14 along the vertical direction, the positioning stud 6 limits the positioning nut 7 and the first U-shaped block 3 to move upwards, the effect that the first U-shaped block 3 swings downwards to abut against the stone plate around the abutting position of the positioning nut 7 is achieved, the rubber sheet 17 is located between the first U-shaped block 3 and the stone plate, when the first U-shaped block 3 compresses the stone plate, the rubber sheet 17 buffers the pressure of the first U-shaped block 3, and the effect that the first U-shaped block 3 is prevented from damaging the stone plate is achieved.

The implementation principle and the beneficial effects of the embodiment are as follows:

when the stone plate is fixed, the first slide bar 15 limits the positioning stud 6 to move in the chute 14 along the vertical direction, the positioning stud 6 moves to be abutted against the stone plate, the positioning stud 6 is abutted against the first U-shaped block 3 at the groove 8, the positioning nut 7 moves to a position close to the first U-shaped block 3 on the positioning stud 6, the backing plate 13 moves to a position between the bottom plate 1 and the driving block 10, the driving rod 11 swings downwards, and a contact point of the driving block 10 and the backing plate 13 gradually rotates to an end point of a semishort shaft from the end point of the semishort shaft, so that the height of the swinging shaft 12 gradually rises, and the effect of driving the second U-shaped block 4 to move upwards is realized.

When the major axis of the vertical elliptical cross section of the driving block 10 moves to the abutting base plate 13, the second U-shaped block 4 moves upwards to the highest point, the second U-shaped block 4 drives the first U-shaped block 3 to swing upwards to abut against the first U-shaped block 3 and the positioning nut 7, the first U-shaped block 3 swings downwards around the abutting position of the first U-shaped block 3 and abuts against the stone plate, the rubber sheet 17 buffers the pressure of the first U-shaped block 3, the first U-shaped block 3 is prevented from damaging the stone plate, and the effect that the first U-shaped block 3 compresses the stone plate is achieved.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (9)

1. The utility model provides a location auxiliary device of energy-saving building stone edging machine which characterized in that: including bottom plate (1) that is used for placing the stone flitch, be provided with fixed block (2) that are used for fixed stone flitch on bottom plate (1), fixed block (2) include first U type piece (3) and second U type piece (4), first U type piece (3) are run through and have been seted up first U type groove (5), be provided with in first U type groove (5) and be used for realizing first U type piece (3) with wobbling locating component takes place in second U type piece (4), second U type piece (4) are run through and have been seted up second U type groove (9), be provided with in second U type groove (9) and be used for the drive second U type piece (4) wobbling drive assembly.

2. The positioning auxiliary device of the energy-saving building stone edge grinding machine according to claim 1, characterized in that: the positioning assembly comprises a positioning stud (6) which is slidably connected to the bottom plate (1) and a positioning nut (7) which is in threaded connection with the positioning stud (6), and a gap used for swinging of the first U-shaped block (3) is reserved between the positioning stud (6) and the bottom wall of the first U-shaped groove (5).

3. The positioning auxiliary device of the energy-saving building stone edge grinding machine according to claim 2, characterized in that: and the first U-shaped block (3) swings to the position that the second U-shaped block (4) is abutted against the lower bottom surface of the positioning nut (7) when the stone plate is extruded and clamped.

4. The positioning auxiliary device of the energy-saving building stone edge grinding machine according to claim 3, characterized in that: the first U-shaped block (3) is provided with a groove (8) which is used for providing a swinging space of the first U-shaped block (3) on the inner wall of the bottom end of the first U-shaped groove (5).

5. The energy-saving positioning auxiliary device of the building stone edge grinding machine according to claim 4, wherein: drive assembly including the level place drive block (10) and sliding connection in backing plate (13) of bottom plate (1), drive block (10) are oval cylindricality, drive block (10) with second U type piece (4) articulate there is swing axle (12), the axis of swing axle (12) passes the central point of drive block (10) both sides, the major axis motion of the vertical oval cross-section of drive block (10) is to the butt during backing plate (13) first U type piece (3) downward swing to with the stone flitch butt.

6. The positioning auxiliary device of the energy-saving building stone edge grinding machine according to claim 5, characterized in that: the driving block (10) is fixedly connected with a driving rod (11), and the axis of the driving rod (11) is overlapped with the short axis of the vertical elliptical cross section of the driving block (10).

7. The energy-saving positioning auxiliary device of the building stone edge grinding machine according to claim 6, characterized in that: the T-shaped sliding groove (14) used for sliding of the positioning stud (6) is formed in the bottom plate (1), the two ends of the bottom plate (1) in the horizontal direction of the sliding groove (14) are provided with openings, and the positioning stud (6) is fixedly connected with a T-shaped first sliding strip (15) which slides in the sliding groove (14).

8. The positioning auxiliary device of the energy-saving building stone edge grinding machine according to claim 7, characterized in that: the backing plate (13) is fixedly connected with a cuboid second sliding strip (16) which slides in the sliding groove (14).

9. The positioning auxiliary device of the energy-saving building stone edge grinding machine according to claim 8, characterized in that: one side of the second U-shaped block (4) close to the stone plate is fixedly connected with a rubber sheet (17).

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