CN111056292A - Material distributing and positioning system for annular end plate of cement pipeline - Google Patents

Abstract

The invention relates to a material distribution and positioning system for an annular end plate of a cement pipeline. The distributing and positioning system of the cement pipeline annular end plate comprises a distributing mechanism and a positioning mechanism, wherein the distributing mechanism comprises an inclined distributing body, a pushing power piece and an introducing rod, the inclined distributing body extends upwards in an inclined mode, a distributing channel is formed in the inclined distributing body and is used for supporting a plurality of annular end plates which are stacked, notches in the annular end plates are arranged downwards, the pushing power piece is used for pushing the annular end plates to be sequentially dropped to the positioning mechanism, one end of the introducing rod is fixed at the end portion of the distributing channel, and the other end of the introducing rod extends downwards in an inclined mode to the upper portion of the positioning mechanism. The material distributing and positioning system of the annular end plate of the cement pipeline is convenient for improving the material distributing effect.

Description

Material distributing and positioning system for annular end plate of cement pipeline

Technical Field

The invention relates to a material distribution and positioning system for an annular end plate of a cement pipeline.

Background

In the field of construction, a ring-shaped pipe pile end plate is a main component of a prestressed cement pipeline, and is generally formed by continuously rolling, spirally winding and then cutting and slicing to form the ring-shaped end plate. However, the ring-shaped end plate has a slit which penetrates the ring-shaped end plate and extends in the radial direction of the ring-shaped end plate. The notch is generated in the previous process and needs to be welded in the subsequent process. However, when the material needs to be distributed, the annular end plate is not easy to be flatly paved on the conveying channel and is easy to fall randomly, so that the material distributing effect is influenced.

Disclosure of Invention

Based on this, it is necessary to provide a distribution and positioning system for the annular end plate of the cement pipeline, which facilitates distribution.

A material distributing and positioning system of a cement pipeline annular end plate, which comprises a material distributing mechanism and a positioning mechanism, the material distributing mechanism comprises an inclined material distributing body, a material pushing power piece and a material guiding rod, the inclined material distributing body extends upwards in an inclined mode, the inclined material distributing body is provided with a material distributing channel which is used for supporting a plurality of annular end plates which are arranged in a stacked mode, the notches on the annular end plates are arranged downwards, the material pushing power piece is used for pushing the annular end plates to sequentially fall onto the positioning mechanism from the inclined material distributing bodies, one end of the feeding rod is fixed at the end part of the material distributing channel, the other end of the feeding rod extends downwards to the upper part of the positioning mechanism in an inclined way, the end part of the feeding rod and the surface of the positioning mechanism are arranged at intervals, the annular end plate is sleeved on the feeding rod by utilizing the notch, and the feeding rod guides the annular end plate to topple and be flatly laid on the positioning mechanism.

In one embodiment, the inclined material distributing body comprises a bottom plate and two side plates, the two side plates are respectively vertically and convexly arranged on two opposite sides of the bottom plate, and the central connecting lines of the plurality of annular end plates are parallel to the extending direction of the material distributing channel.

In one embodiment, one end of the inclined distributing body is provided with a baffle plate, and two opposite ends of the baffle plate are respectively fixed to the end parts of the two side plates.

In one embodiment, two first support rods are arranged on the bottom plate, and a second support rod is convexly arranged on each side plate.

In one embodiment, the two first support rods are supported at the bottom of the ring-shaped end plate and are respectively positioned at two opposite sides of the notch.

In one embodiment, each side plate is provided with an inclined support plate protruding upwards, the second support rod is arranged at the top edge of the inclined support plate, and the second support rods of the two side plates are used for supporting two opposite sides of the annular end plate.

In one embodiment, the distribution channel includes a starting end and a terminating end, the starting end is disposed adjacent to the baffle, and the terminating end is disposed adjacent to the end of the feeding rod.

In one embodiment, a sensor is arranged at the termination end and used for sensing whether the annular end plate falls or not, and when the annular end plate falls, the pushing power piece stops pushing materials.

When the distribution and positioning system of the cement pipeline annular end plate is used, the cement pipeline annular end plate is pushed by the material pushing power piece, the annular end plates arranged in a plurality of stacked modes move to the end part of the distribution channel and then are sequentially pushed down by the annular end plates, so that the annular end plates drop to the material guiding rods, the material guiding rods enter the annular end plates from the notches, the annular end plates are guided to be toppled and flatly laid on the positioning mechanism, and the positioning mechanism positions the annular end plates and then conveys the annular end plates. The pusher power unit then pushes down a ring-shaped end plate. In the invention, the annular end plate can be guided to topple and tile by arranging the feeding rod, so that the annular end plate can be orderly tiled on the positioning mechanism, and the material distributing effect is improved.

Drawings

Fig. 1 is a schematic perspective view of a distributing and positioning system for a ring-shaped end plate of a cement pipeline according to an embodiment.

FIG. 2 is a perspective view of another view of the material distribution and positioning system for the annular end plate of the cement pipe shown in FIG. 1.

Fig. 3 is a partially enlarged view of a portion a in fig. 2.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The invention relates to a material distribution and positioning system for an annular end plate of a cement pipeline. For example, the material distributing and positioning system of the annular end plate of the cement pipeline comprises a material distributing mechanism and a positioning mechanism, wherein the material distributing mechanism comprises an inclined material distributing body, a material pushing power piece and a material guiding rod, and the inclined material distributing body extends upwards in an inclined mode. For example, the inclined material distributing body is provided with a material distributing channel, the material distributing channel is used for supporting a plurality of annular end plates which are arranged in a stacked mode, and the notches on the annular end plates are arranged downwards. For example, the material pushing power piece is used for pushing the annular end plates to sequentially drop from the inclined material distributing body to the positioning mechanism, one end of the material feeding rod is fixed at the end of the material distributing channel, and the other end of the material feeding rod obliquely extends downwards to the position above the positioning mechanism. For example, the end of the priming lever is spaced from the surface of the positioning mechanism. For example, the ring-shaped end plate is sleeved on the feeding rod by the notch, and the feeding rod guides the ring-shaped end plate to be poured and laid on the positioning mechanism.

Referring to fig. 1 to 3, a distributing and positioning system for a cement pipeline annular end plate includes a distributing mechanism 30 and a positioning mechanism 50, where the distributing mechanism 30 includes an inclined distributing body 31, a pushing power member (not shown), and a feeding rod 33, the inclined distributing body 31 extends obliquely upward, a distributing channel 310 is formed on the inclined distributing body 31, the distributing channel 310 is used to support a plurality of annular end plates 100 arranged in a stacked manner, a notch 105 on the annular end plate 100 is arranged downward, the pushing power member is used to push the plurality of annular end plates 100 to sequentially drop from the inclined distributing body 31 onto the positioning mechanism 50, one end of the feeding rod 33 is fixed to an end of the distributing channel 310, the other end of the feeding rod extends obliquely downward to above the positioning mechanism 50, an end of the feeding rod 33 is spaced from a surface of the positioning mechanism 50, the ring-shaped end plate 100 is sleeved on the feeding rod 33 by the cut-out 105, and the feeding rod 33 guides the ring-shaped end plate 100 to be toppled and laid on the positioning mechanism 50.

For example, when the material distributing and positioning system of the cement pipeline ring-shaped end plate is used, the material pushing power piece pushes the plurality of stacked ring-shaped end plates 100 to move to the end of the material distributing channel 310, and then the plurality of ring-shaped end plates 100 are sequentially pushed down, so that the ring-shaped end plates 100 fall onto the material guiding rods 33, the material guiding rods 33 enter the ring-shaped end plates 100 from the notches 105, the material guiding rods 33 guide the ring-shaped end plates 100 to topple and lay on the positioning mechanism 50, and the positioning mechanism 50 positions the ring-shaped end plates and then conveys the ring-shaped end plates out. The pusher power assembly then pushes down on a ring-shaped end plate 100. In the invention, the annular end plate 100 can be guided to tilt and tile by arranging the feeding rod 33, so that the annular end plate can be orderly tiled on the positioning mechanism 50, and the material distributing effect is improved.

For example, in order to support the ring-shaped end plates 100, the inclined material dividing body 31 includes a bottom plate 311 and two side plates 312, the two side plates 312 are respectively vertically protruded from two opposite sides of the bottom plate 311, and a central connecting line of the plurality of ring-shaped end plates 100 is parallel to an extending direction of the material dividing channel 310. I.e., the plurality of ring-shaped end plates 100 are vertically arranged. One end of the inclined distributing body 31 is provided with a baffle 313, and opposite ends of the baffle 313 are respectively fixed to the ends of the two side plates 312. Two first support rods 314 are arranged on the bottom plate 311, and a second support rod 315 is convexly arranged on each side plate 312. The two first support rods 314 are supported at the bottom of the ring-shaped end plate 100 and located at two opposite sides of the notch 105. Each of the side plates 312 is provided with an inclined support plate 316 in a protruding manner, the second support bars 315 are arranged at the top edge of the inclined support plate 316, and the second support bars 315 of the two side plates 312 are used for supporting two opposite sides of the ring-shaped end plate 100. By providing the two first support bars 314 and the two second support bars 315, the bottom and both sides of the ring-shaped end plate 100 can be supported, and the support stability of the ring-shaped end plate 100 is improved.

For example, in order to facilitate pushing one by one, after one of the ring-shaped end plates 100 is pushed down, the other ring-shaped end plate 100 is pushed down, the material distribution channel 310 includes a starting end 317 and a terminating end 318 which are oppositely arranged, the starting end 317 is arranged adjacent to the baffle 313, and the terminating end 318 is arranged adjacent to the end of the feeding rod 33. The terminating end 318 is provided with a sensor for sensing whether the annular end plate 100 falls or not, and when the annular end plate 100 falls, the material pushing power piece stops pushing material. Through the arrangement of the sensor, when the annular end plate 100 falls down in sensing, pushing can be stopped, the annular end plate 100 can be enabled to be intermittent for a section and then pushed, the annular end plates 100 can be sequentially conveyed, and material distribution operation can be achieved.

For example, it is particularly important that in order to facilitate guiding the ring-shaped end plate 100 to topple, the feed rod 33 includes an opposite cut-in end 331 and an opposite cut-out end 332, the cut-in end 331 protruding over the terminal end 318 of the feed channel 310 and being aligned with the cut-out 105 of the ring-shaped end plate 100. The thickness of the cut-in end 331 is smaller than the width of the cut-out 105, the lead-out end 332 is located above the positioning mechanism 50, and the thickness of the lead-out end 332 is larger than the width of the cut-out 105. The thickness of the end of the feeding rod 33 is set so that the ring-shaped end plate 100 can be firstly sleeved on the feeding rod 33 and obliquely slide down, then the side of the ring-shaped end plate 100 with the notch 105 is firstly abutted on the positioning mechanism 50, so that the side far away from the notch 105 is inclined and slides along the ring-shaped end plate 100, and the leading-out end 332 is pulled out and tiled on the positioning mechanism 50, and the feeding rod 33 is set so that the ring-shaped end plate 100 can be smoothly tiled on the positioning mechanism 50.

For example, the height position of the terminating end 318 is greater than the height position of the starting end 317, the positioning mechanism 50 is located below the terminating end 318, and a conveying line (not shown) is disposed at one end of the positioning mechanism 50. In order to adjust the circle center of the ring-shaped end plate 100 conveniently, so that the ring-shaped end plate 100 aligns the conveying line, and it is convenient for follow-up conveying to the ring-shaped end plate 100, the positioning mechanism 50 includes positioning element 51 and conveying element 55, positioning element 51 includes positioning plate 511, mounting disc 512, spiral drive body 513 and four drive columns 514, positioning plate 511 is rectangular strip plate-shaped, positioning plate 511 is close to the one end of terminating end 318 is formed with the positioning area, the positioning area is square area, strip-shaped groove 5115 has been seted up respectively to four corners department of positioning area, every one end of strip-shaped groove 5115 is located the bight department of positioning area, the other end extends towards the center of positioning area. The side length of the positioning area is larger than the outer diameter of the annular end plate 100, and the annular end plate 100 is used for falling onto the positioning area. The distance between the lead-out end 332 of the feed bar 33 and the surface of the positioning region is larger than the thickness of the ring-shaped end plate 100. The mounting disc 512 is fixed in the below of locating plate 511, four guide grooves have been seted up on the mounting disc 512, the position of four guide grooves respectively with four the position of bar groove 5115 is corresponding, servo motor (not shown) is installed at the center of mounting disc 512, the center of screw drive body 513 is fixed in the top of servo motor's output shaft, the screw drive body 513 is located the below of locating plate 511, be formed with screw drive groove 5135 on the screw drive body 513, four drive columns 514 wear to locate respectively in four bar grooves 5115, the bottom of four drive columns 514 is inserted respectively with sliding ground and is located in four guide grooves, the middle part of four drive columns 514 is all worn to locate in the screw drive groove 5135 of screw drive body 513. The four driving posts 514 are all cylindrical rods, and the diameter of the driving post 514 is larger than the width of the notch 105 of the ring-shaped end plate 100.

When the ring-shaped end plate 100 needs to be guided to align with the conveying line, the four driving columns 514 are initially located at one end of the four strip-shaped grooves 5115 away from the center of the positioning area, when the ring-shaped end plate 100 falls onto the positioning area, the servo motor is configured to drive the spiral driving body 513 to rotate, so as to cause the four driving columns 514 to move in the spiral driving grooves 5135, so that the four driving columns 514 move towards the center of the positioning area along the four strip-shaped grooves 5115, and the four driving columns 514 push the ring-shaped end plate 100 to move until the center of the ring-shaped end plate 100 is located at the center of the positioning area. Alignment of the end ring 100 with the conveyor line is now complete, after which the servo motor is rotated in reverse to drive the four drive columns 514 back out away from the end ring 100.

For example, in order to facilitate pushing the ring-shaped end plate 100 to the conveying line, a guide rail 5118 is formed on a side of the positioning plate 511 away from the material distribution mechanism 30, the conveying assembly 55 includes a conveying motor 551, a sliding block 552, a shifting frame 553, and a lifting motor 554, the conveying motor 551 is mounted on an end of the positioning plate 511, the sliding block 552 is slidably disposed on the guide rail 5118 and connected to an output shaft of the conveying motor 551, the shifting frame 553 is connected to the sliding block 552 and extends above the positioning area, the lifting motor 554 is mounted on an end of the shifting frame 553, a shifting rod 555 is fixed on an output shaft of the lifting motor 554, the shifting rod 555 extends towards the positioning area, and the shifting rod 555 is located above a central axis of the positioning plate 511. The projection of the feeding rod 33 on the positioning plate 511 is defined as a projection straight line, and the projection straight line passes through the center of the positioning area and is perpendicular to the conveying direction of the conveying line. The poke rod 555 is arranged on one side of the priming lever 33 facing the conveying flow line. When it is desired to dial the ring-shaped end plate 100 into the conveying line, the lifting motor 554 drives the dial rod 555 to move towards the positioning area so that the end of the dial rod 555 moves to the inside of the ring-shaped end plate 100, and thereafter the conveying motor 551 drives the sliding block 552 to move towards the conveying line, thereby dialing the ring-shaped end plate 100 into the conveying line by means of the dial rod 555. By positioning the poke rod 555, the ring-shaped end plate 100 can keep aligned with the conveying flow line during moving to the conveying flow line.

For example, to facilitate adjustment of the angle of inclination of the feed rod 33 for ring-shaped end plates 100 of different diameters and weights, the terminating end 318 is recessed with a mounting groove into which the cutting end 331 of the feed rod 33 is rotatably connected by a rotating shaft, and the end of the cutting end 331 protrudes into the feed channel 310 and is aligned with the notch 105. The positioning mechanism 50 further includes a turning assembly 58, the turning assembly 58 includes a turning cylinder and a V-shaped abutting plate 583, the turning cylinder is mounted on an edge of one side of the positioning plate 511, which is far away from the guide rail 5118, the V-shaped abutting plate 583 is mounted on an output shaft of the turning cylinder, and the V-shaped abutting plate 583 is blocked at an edge of one side of the positioning area, which is far away from the guide rail 5118, and is used for blocking the annular end plate 100 from sliding out of the positioning area. The top of the V-shaped abutting plate 583 is provided with an abutting block in a protruding manner, and the abutting block abuts against the bottom of the feeding rod 33 and is adjacent to the cutting end 331. The overturning cylinder is used for driving the V-shaped abutting plate 583 to abut against the feeding rod 33 to change the inclination angle and change the distance between the leading-out end 332 and the positioning area. Through the turning assembly 58, on one hand, the annular end plate 100 can be prevented from falling out of the positioning area, on the other hand, the inclination angle of the feeding rod 33 can be changed, and the distance from the leading-out end 332 to the positioning area can be changed, thereby achieving three purposes. By design, the V-shaped holding plate 583 does not contact the notch 105 of the ring-shaped end plate 100 when sliding off.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (8)

1. A material distributing and positioning system for annular end plates of cement pipelines is characterized by comprising a material distributing mechanism and a positioning mechanism, wherein the material distributing mechanism comprises an inclined material distributing body, a material pushing power piece and a material guiding rod, the inclined material distributing body extends upwards in an inclined mode, a material distributing channel is formed in the inclined material distributing body and used for supporting a plurality of annular end plates arranged in a stacked mode, notches in the annular end plates are arranged downwards, the material pushing power piece is used for pushing the annular end plates to sequentially fall onto the positioning mechanism from the inclined material distributing body, one end of the material guiding rod is fixed to the end portion of the material distributing channel, the other end of the material guiding rod extends downwards in an inclined mode to the position above the positioning mechanism, the end portion of the material guiding rod and the surface of the positioning mechanism are arranged at intervals, and the annular end plates are sleeved on the material guiding rod through the notches, the annular end plate is guided by the feeding rod to be toppled and laid on the positioning mechanism.

2. The system for distributing and positioning the annular end plates of the cement pipelines according to claim 1, wherein the inclined distributing body comprises a bottom plate and two side plates, the two side plates are vertically and convexly arranged on two opposite sides of the bottom plate respectively, and the central connecting lines of the plurality of annular end plates are parallel to the extending direction of the distributing channel.

3. The cement pipeline ring-shaped end plate distributing and positioning system as claimed in claim 2, wherein one end of the inclined distributing body is provided with a baffle plate, and the two opposite ends of the baffle plate are respectively fixed at the ends of the two side plates.

4. The system of claim 3, wherein the bottom plate has two first support rods and each of the side plates has a second support rod protruding therefrom.

5. The system of claim 4, wherein the two first support rods are supported at the bottom of the ring-shaped end plate and located at two opposite sides of the cut.

6. The system of claim 5, wherein each side plate has an inclined support plate protruding therefrom, the second support bar is disposed at a top edge of the inclined support plate, and the second support bars of the two side plates are used for supporting two opposite sides of the annular end plate.

7. The system of claim 6, wherein the distribution channel includes an initial end and a terminal end, the initial end is disposed adjacent to the baffle plate, and the terminal end is disposed adjacent to the end of the rod.

8. The system for distributing and positioning the annular end plate of the cement pipe as claimed in claim 7, wherein a sensor is disposed at the terminating end for sensing whether the annular end plate falls, and when the annular end plate falls, the pushing power device stops pushing.

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