CN111521488A - Hollow brick resistance to compression detection device - Google Patents

Abstract

One or more embodiments of the specification provide an air brick compression resistance detection device, which comprises a support and a belt conveyor, wherein supporting legs are arranged at the bottom of the support, an installation frame is arranged at the middle position of the top of the support, and the belt conveyor is arranged inside the support; still include feed mechanism and resistance to compression detection mechanism, feed mechanism is located intermediate position on the support, resistance to compression detection mechanism sets up on the mounting bracket, resistance to compression detection mechanism includes second motor, second connecting rod, first connecting rod, slider and detects the head, the second motor sets up inside the mounting bracket, the one end of second connecting rod and the output fixed connection of second motor, the one end of first connecting rod rotates with the other end of second connecting rod to be connected, slider sliding connection is inside the mounting bracket, the other end of first connecting rod rotates to be connected on the slider, detect the head setting and be close to the side of belt feeder at the slider, and detect the head and run through a side that the mounting bracket is close to the belt feeder.

Description

Hollow brick resistance to compression detection device

Technical Field

One or more embodiments of this description relate to air brick production facility field, especially relate to an air brick resistance to compression detection device.

Background

The hollow brick is usually used for non-bearing parts, the hole rate is equal to or more than 35 percent, and the hollow brick with large size and small quantity is called a hollow brick. The hollow bricks are divided into cement hollow bricks, clay hollow bricks and shale hollow bricks. The hollow brick is a main wall material commonly used in the construction industry, and has become a product recommended by national construction departments firstly due to the advantages of light weight, less consumption of raw materials and the like. Similar to red bricks, the common raw materials for making hollow bricks are clay and cinder ash.

The hollow brick is comparatively extensive in the building trade application in prior art, and today requires more and more high to the compressive capacity of hollow brick, but traditional hollow brick mostly relies on the manual work to carry out the sample detection, and efficiency is lower, and the result that the sample detected can't represent the compressive capacity of hollow brick in batches, to sum up, this application now provides a hollow brick compressive detection device and solves the problem that the aforesaid appears.

Disclosure of Invention

In view of the above, an object of one or more embodiments of the present disclosure is to provide a solution to the problem.

In view of the above, one or more embodiments of the present disclosure provide an air brick compression-resistant detection apparatus, which includes a support and a belt conveyor, wherein the support is provided with support legs at a bottom thereof, a mounting frame is disposed at a middle position of a top of the support, and the belt conveyor is disposed inside the support; still include feed mechanism and resistance to compression detection mechanism, feed mechanism is located the intermediate position on the support, resistance to compression detection mechanism sets up on the mounting bracket.

Preferably, feed mechanism includes pivot, two mount pads and first motor, be provided with the bearing frame on the support, the pivot is rotated and is connected inside the bearing frame, two mount pad symmetries are fixed at the both ends of pivot, are four sector plates of annular equidistance having arranged on every mount pad, and the hollow brick standing groove is constituteed in the clearance between the adjacent sector plate, first motor welding is on the support, and the output fixed connection of pivot and first motor.

Preferably, resistance to compression detection mechanism includes second motor, second connecting rod, first connecting rod, slider and detects the head, the second motor sets up inside the mounting bracket, the one end of second connecting rod and the output fixed connection of second motor, the one end of first connecting rod rotates with the other end of second connecting rod to be connected, slider sliding connection is inside the mounting bracket, the other end of first connecting rod rotates to be connected on the slider, it sets up the side that is close to the belt feeder at the slider to detect the head, and detects the head and runs through the side that the mounting bracket is close to the belt feeder.

More preferably, resistance to compression detection mechanism still includes sleeve pipe and pressure boost spring, the fixed side that sets up at the slider and be close to the belt feeder of sleeve pipe, pressure boost spring sets up at the intraductal portion of cover, and pressure boost spring and detection head fixed connection, and the one end that detects the head and keep away from the belt feeder stretches into the intraductal portion of cover.

More preferably, still include fourth motor, lack tooth gear and drive gear, the fourth motor welding is on the support, lack tooth gear setting on the output of fourth motor, drive gear and the coaxial fixed rotation of the roller of belt feeder are connected inside the support, it is connected with drive gear transmission through the chain to lack tooth gear.

More preferably, the output end of the fourth motor is in transmission connection with the shaft of the second connecting rod through the transmission belt.

More preferred, still include carousel, two round pin axles and driving plate, the carousel is rotated by fourth motor drive, and two round pin axle symmetries set up on the surface of carousel, driving plate and the coaxial fixed connection of mount pad, and the outer lane of driving plate is annular equidistance and has seted up four transmission grooves, transmission groove and round pin axle phase-match.

According to the invention, the hollow brick is conveyed to the inside of the hollow brick placing groove through the belt conveyor, the first motor is matched with the two mounting seats of the rotating shaft to form a structure to drive the hollow brick to rotate, so that the stability of the hollow brick when being detected is maintained, the detection precision is improved, and the problems of difficult cleaning and low safety caused by the fact that the hollow brick is not enough in compression resistance and splashes around are prevented; according to the invention, the second motor is matched with a mechanical structure consisting of the second connecting rod, the first connecting rod and the sliding block to drive the detection head to reciprocate up and down, and the feeding mechanism is matched to continuously detect the compression resistance of batch hollow bricks, so that manual sampling detection is replaced, the accuracy of results is improved, and the detection efficiency is improved; the belt conveyor is driven to intermittently run by the fourth motor in cooperation with the toothless gear and the transmission gear, and the turntable, the two pin shafts and the transmission plate are matched to drive the hollow brick to intermittently rotate, so that the matching degree of the whole equipment is improved, all mechanisms are driven by one motor, the production cost is reduced, and the efficiency is further improved.

According to the invention, the hollow brick is conveyed to the inside of the hollow brick placing groove through the belt conveyor, the first motor is matched with the two mounting seats of the rotating shaft to form a structure to drive the hollow brick to rotate, so that the stability of the hollow brick when being detected is maintained, the detection precision is improved, and the problems of difficult cleaning and low safety caused by the fact that the hollow brick is not enough in compression resistance and splashes around are prevented; according to the invention, the second motor is matched with a mechanical structure consisting of the second connecting rod, the first connecting rod and the sliding block to drive the detection head to reciprocate up and down, and the feeding mechanism is matched to continuously detect the compression resistance of batch hollow bricks, so that manual sampling detection is replaced, the accuracy of results is improved, and the detection efficiency is improved; the belt conveyor is driven to intermittently run by the fourth motor in cooperation with the toothless gear and the transmission gear, and the turntable, the two pin shafts and the transmission plate are matched to drive the hollow brick to intermittently rotate, so that the matching degree of the whole equipment is improved, all mechanisms are driven by one motor, the production cost is reduced, and the efficiency is further improved.

Drawings

In order to more clearly illustrate one or more embodiments or prior art solutions of the present specification, the drawings that are needed in the description of the embodiments or prior art will be briefly described below, and it is obvious that the drawings in the following description are only one or more embodiments of the present specification, and that other drawings may be obtained by those skilled in the art without inventive effort from these drawings.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a feeding mechanism according to the present invention;

FIG. 3 is a schematic structural view of the anti-compression detection mechanism of the present invention;

FIG. 4 is a schematic structural diagram of a preferred embodiment of the present invention;

in the reference symbols: 1. a support; 2. a support leg; 3. a feeding mechanism; 4. a belt conveyor; 5. a compression resistance detection mechanism; 6. a mounting frame; 7. a hollow brick body; 8. a transmission gear; 9. a gear with missing teeth; 10. a pin shaft; 11. a transmission belt; 12. a drive plate; 13. a turntable; 14. a third motor; 15. a chain; 301. a sector plate; 302. a rotating shaft; 303. a mounting seat; 304. a first motor; 501. a second motor; 502. a slider; 503. a pressurizing spring; 504. a detection head; 505. an orientation sleeve; 506. a first link; 507. a second link; a. a hollow brick placing groove; b. a transmission groove.

Detailed Description

For the purpose of promoting a better understanding of the objects, aspects and advantages of the present disclosure, reference is made to the following detailed description taken in conjunction with the accompanying drawings.

It is to be noted that unless otherwise defined, technical or scientific terms used in one or more embodiments of the present specification should have the ordinary meaning as understood by those of ordinary skill in the art to which this disclosure belongs. The use of "first," "second," and similar terms in one or more embodiments of the specification is not intended to indicate any order, quantity, or importance, but rather is used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

Example one

Referring to fig. 1 and 3, the hollow brick compression-resistant detection device comprises a support 1 and a belt conveyor 4, wherein support legs 2 are arranged at the bottom of the support 1, an installation frame 6 is arranged at the middle position of the top of the support 1, and the belt conveyor 4 is arranged inside the support 1; still include feed mechanism 3 and resistance to compression detection mechanism 5, feed mechanism 3 is located the intermediate position on support 1, resistance to compression detection mechanism 5 sets up on mounting bracket 6.

Resistance to compression detection mechanism 5 includes second motor 501, second connecting rod 507, first connecting rod 506, slider 502 and detects head 504, second motor 501 sets up inside mounting bracket 6, the one end of second connecting rod 507 and the output fixed connection of second motor 501, the one end of first connecting rod 506 rotates with the other end of second connecting rod 507 to be connected, slider 502 sliding connection is inside mounting bracket 6, the other end of first connecting rod 506 rotates to be connected on slider 502, detect that head 504 sets up the side that is close to belt feeder 4 at slider 502, and detect that head 504 runs through a side that mounting bracket 6 is close to belt feeder 4.

The anti-compression detection mechanism 5 further comprises an orientation sleeve 505 and a pressurizing spring 503, the orientation sleeve 505 is fixedly arranged on one side surface of the sliding block 502 close to the belt conveyor 4, the pressurizing spring 503 is arranged inside the orientation sleeve 505, the pressurizing spring 503 is fixedly connected with the detection head 504, and one end, far away from the belt conveyor 4, of the detection head 504 extends into the orientation sleeve 505.

The working process is as follows: the hollow brick to be detected is placed on the surface of the belt conveyor 4, the belt conveyor 4 is operated, when the belt conveyor 4 drives the hollow brick to be detected to move towards the lower part of the detection head 504, the belt conveyor 4 stops operating the belt conveyor 4, the second motor 501 is operated, the output end of the second motor 501 rotates to drive the second connecting rod 507 to rotate, the second connecting rod 507 drives the first connecting rod 506 to swing, the first connecting rod 506 swings to drive the sliding block 502 to reciprocate up and down in the mounting frame 6, the sliding block 502 drives the detection head 504 to move downwards and exert force on the hollow brick, the hollow brick exerts reaction force on the detection head 504 and drives the detection head 504 to move towards the direction of compressing the pressurizing spring 503 in the orientation sleeve 505, meanwhile, the pressurizing spring 503 exerts another reaction force on the detection head 504 due to the elasticity of the pressurizing spring 503, the purpose of ensuring that the pressure of the detection head 504 on the hollow brick achieves the, the operation belt feeder 4, belt feeder 4 take away the air brick that finishes that detects, carry the next air brick that waits to detect the head 504 below to supply to continue to detect, whether the air brick surface after the user of service observes the detection is impaired, judges the compressive capacity of air brick.

Example two

As a preferable scheme of the first embodiment, please refer to fig. 2, the feeding mechanism 3 includes a rotating shaft 302, two installation bases 303 and a first motor 304, a bearing seat is disposed on the bracket 1, the rotating shaft 302 is rotatably connected inside the bearing seat, the two installation bases 303 are symmetrically fixed at two ends of the rotating shaft 302, four sector plates 301 are annularly and equidistantly arranged on each installation base 303, a gap between adjacent sector plates 301 forms a hollow brick placing groove a, the first motor 304 is welded on the bracket 1, and the rotating shaft 302 is fixedly connected with an output end of the first motor 304.

The working process is as follows: the belt conveyor 4 is operated, the belt conveyor 4 drives the hollow bricks to be detected to move to the inside of a hollow brick placing groove a parallel to a belt of the belt conveyor 4, the first motor 304 is operated, the output end of the first motor 304 rotates to drive the rotating shaft 302 to rotate, the rotating shaft 302 drives the mounting seat 303 to rotate, the mounting seat 303 drives the sector plate 301 to rotate, after the sector plate 301 drives the hollow bricks to be detected to rotate for 90 degrees, the first motor 304 is stopped to operate, the second motor 501 is operated, the same steps as the first embodiment are carried out, the compression resistance of the hollow bricks to be detected is detected, in the detection process, the belt conveyor 4 is operated, the belt conveyor 4 moves the hollow bricks on the belt to the inside of the hollow brick placing groove a parallel to the belt of the belt conveyor 4, after the detection is finished, the first motor 304 is operated, the sector plate 301 is driven to rotate for 90 degrees in the same direction, and the detected hollow bricks are returned to the belt of, and drives the next hollow brick to be detected to rotate to the position below the detection head 504 for detection, so that the hollow brick to be detected on the belt conveyor 4 is continuously detected in a reciprocating manner.

EXAMPLE III

As a preferable scheme of the first embodiment and the second embodiment, the belt conveyor further comprises a third motor 14, a tooth-missing gear 9 and a transmission gear 8, wherein the third motor 14 is welded on the support 1, the tooth-missing gear 9 is arranged at the output end of the third motor 14, the transmission gear 8 and a roller shaft of the belt conveyor 4 are coaxially and fixedly connected inside the support 1 in a rotating mode, and the tooth-missing gear 9 is in transmission connection with the transmission gear 8 through a chain 15.

The output end of the third motor 14 is in transmission connection with the shaft of the second connecting rod 507 through the transmission belt 11.

Still include carousel 13, two round pin axles 10 and driving plate 12, carousel 13 is rotated by the drive of third motor 14, and two round pin axle 10 symmetries set up on the surface of carousel 13, driving plate 12 and the coaxial fixed connection of mount pad 303, and the outer lane of driving plate 12 is annular equidistance and has seted up four driving groove b, driving groove b and round pin axle 10 phase-matches.

The working process is as follows: when the third motor 14 is operated, the output end of the third motor 14 rotates to drive the gear 9 with missing teeth to rotate, the gear 9 with missing teeth cooperates with the chain 15 to drive the transmission gear 8 to intermittently rotate, and the transmission gear 8 drives the belt conveyor 4 to intermittently operate.

The output end of the third motor 14 rotates to drive the rotating disc 13 to rotate, the rotating disc 13 drives the pin shaft 10 to rotate, the pin shaft 10 is driven to reciprocate in and out of and slide in the transmission grooves b of the transmission plates 12, the pin shaft 10 enters one of the transmission grooves b to drive the transmission plates 12 to rotate, the pin shaft 10 is ready to enter the next transmission groove b in the process of leaving the transmission groove b, the transmission plates 12 stop rotating, and therefore reciprocation is achieved, and the rotating shaft 302 is driven to intermittently rotate.

The output end of the third motor 14 rotates to drive the transmission belt 11 to drive the second connecting rod 507 to rotate, and the second connecting rod 507 drives the first connecting rod 506 to rotate.

The steps are the same as those in the first and second embodiments, except that when the belt conveyor 4 moves the hollow brick to be detected into the hollow brick placing groove a, the belt conveyor 4 stops moving, the rotating shaft 302 rotates to drive the hollow brick to be detected to rotate for 90 degrees, the rotating shaft 302 stops rotating, the belt conveyor 4 continues to operate to complete the process just before, in the process of rotating the rotating shaft 302, the detection head 504 moves upwards, when the rotating shaft 302 stops rotating, the detection head 504 moves downwards and completes the operation of the anti-compression detection, when the detection head 504 moves upwards again, the rotating shaft 302 drives the hollow brick which is detected to rotate for 90 degrees in the same direction, and the hollow brick which is detected is placed on the belt conveyor 4, in the process, the belt conveyor 4 stops rotating, after the rotation is completed, the belt conveyor 4 operates again to drive the hollow brick to be detected to enter the hollow brick placing groove a, and simultaneously drives the hollow brick which is detected to leave the hollow brick placing groove a, therefore, the detection of all the hollow bricks to be detected on the belt conveyor 4 is completed.

It is intended that the one or more embodiments of the present specification embrace all such alternatives, modifications and variations as fall within the broad scope of the appended claims. Therefore, any omissions, modifications, substitutions, improvements, and the like that may be made without departing from the spirit and principles of one or more embodiments of the present disclosure are intended to be included within the scope of the present disclosure.

Claims (7)

1. An air brick resistance to compression detection device includes:

the support comprises a support (1), wherein supporting legs (2) are arranged at the bottom of the support (1), and a mounting frame (6) is arranged in the middle of the top of the support (1); and

the belt conveyor (4), the belt conveyor (4) is arranged inside the bracket (1);

it is characterized by also comprising:

the feeding mechanism (3) is positioned in the middle of the support (1); and

the compression resistance detection mechanism (5) is arranged on the mounting frame (6).

2. A hollow brick compression resistance detection device according to claim 1, characterized in that the feeding mechanism (3) comprises:

the support (1) is provided with a bearing seat, and the rotating shaft (302) is rotatably connected inside the bearing seat;

the two installation seats (303) are symmetrically fixed at two ends of the rotating shaft (302), four fan-shaped plates (301) are annularly and equidistantly arranged on each installation seat (303), and gaps between the adjacent fan-shaped plates (301) form a hollow brick placing groove (a); and

the first motor (304), the first motor (304) is welded on the support (1), and the rotating shaft (302) is fixedly connected with the output end of the first motor (304).

3. A hollow brick compression resistance detection device according to claim 1, characterized in that the compression resistance detection mechanism (5) comprises:

the second motor (501), the second motor (501) is arranged inside the mounting rack (6);

one end of the second connecting rod (507) is fixedly connected with the output end of the second motor (501);

a first connecting rod (506), wherein one end of the first connecting rod (506) is rotatably connected with the other end of the second connecting rod (507);

the sliding block (502) is connected inside the mounting frame (6) in a sliding mode, and the other end of the first connecting rod (506) is connected to the sliding block (502) in a rotating mode; and

detect head (504), detect head (504) and set up the side that is close to belt feeder (4) at slider (502), and detect head (504) and run through a side that mounting bracket (6) are close to belt feeder (4).

4. A hollow brick compression resistance detection device according to claim 3, characterized in that the compression resistance detection mechanism (5) further comprises:

the orientation sleeve (505) is fixedly arranged on one side surface, close to the belt conveyor (4), of the sliding block (502); and

the pressurizing spring (503) is arranged inside the directional sleeve (505), the pressurizing spring (503) is fixedly connected with the detection head (504), and one end, far away from the belt conveyor (4), of the detection head (504) extends into the directional sleeve (505).

5. A hollow brick compression resistance testing device according to claim 3, further comprising:

the third motor (14), the said third motor (14) is welded on support (1);

the gear (9) with missing teeth is arranged on the output end of the third motor (14); and

the transmission gear (8) is coaxially, fixedly and rotatably connected with a roller shaft of the belt conveyor (4) inside the support (1), and the tooth-missing gear (9) is in transmission connection with the transmission gear (8) through a chain (15).

6. A hollow brick compression resistance detection device according to claim 5, characterized in that the device also comprises a transmission belt (11), and the output end of the third motor (14) is in transmission connection with the shaft of the second connecting rod (507) through the transmission belt (11).

7. A hollow brick compression resistance detection device according to claim 5, further comprising:

the rotary table (13), the said rotary table (13) is driven by the third electrical machinery (14) to rotate;

the two pin shafts (10) are symmetrically arranged on the surface of the rotary table (13); and

driving plate (12), driving plate (12) and the coaxial fixed connection of mount pad (303), and the outer lane of driving plate (12) is the annular equidistance and has seted up four transmission grooves (b), transmission groove (b) and round pin axle (10) phase-match.

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