CN214925475U - Blank size detection device for processing refractory bricks - Google Patents

Abstract

A blank size detection device for processing refractory bricks comprises a base, a processing table arranged at the top of the base, a transmission roller rotatably arranged on one side of the processing table, and a frame arranged on one side of the upper surface of the processing table, wherein a size adjusting assembly is arranged at the top of the frame, and a guide assembly is arranged on the side surface of the processing table; size adjusting part includes the crossbearer, and the crossbearer sets up on the side in the frame, and the crossbearer bottom sets up the adjustment tank, and the adjustment tank internal rotation sets up horizontal lead screw, sets up the screw on the horizontal lead screw, and the screw bottom sets up the plummer, and horizontal lead screw one end is connected with driving motor's drive shaft through the shaft coupling, and driving motor sets up at crossbearer side surface, and plummer side surface sets up the pointer, and pointer one end extends to scale one side, and the scale setting is on crossbearer side surface. The utility model discloses can carry out the accurate regulation to the cutting distance, can satisfy the processing of different length blanks, guarantee the blank and remove the guidance quality simultaneously, improve and measure and cut the accuracy.

Description

Blank size detection device for processing refractory bricks

Technical Field

The utility model relates to a resistant firebrick processing technology field especially relates to a resistant firebrick processing is with blank size detection device.

Background

The refractory brick is called firebrick for short, and is a refractory material fired by refractory clay or other refractory raw materials. In the production of refractory bricks, it is necessary to cut a refractory brick blank into a strip of a desired length and then cut the strip-shaped refractory brick blank into rectangular-shaped refractory bricks by thread cutting or the like. During the cutting operation of the refractory brick blank, the dimension of the refractory brick blank in the feeding state needs to be detected.

Traditional blank size detection device can't adjust the length of cutting, can't realize automatic cutout, and machining efficiency is not high, and traditional blank size detection device can't remove to resistant firebrick blank simultaneously and lead, influences the later stage and cuts off the precision.

SUMMERY OF THE UTILITY MODEL

Objects of the invention

For solving the technical problem that exists among the background art, the utility model provides a blank size detection device is used in processing of nai firebrick can carry out the accuracy to the cutting distance and adjust, can satisfy the processing of different length blanks, guarantees the blank and removes the guidance quality simultaneously, improves and measures and the cutting accuracy.

(II) technical scheme

The utility model provides a blank size detection device for processing refractory bricks, which comprises a frame, a processing table arranged at the top of the frame, a driving roller arranged on one side of the processing table in a rotating way, and a frame arranged on one side of the upper surface of the processing table, wherein the top of the frame is provided with a size adjusting assembly, and the side surface of the processing table is provided with a guide assembly;

size adjusting part includes the crossbearer, and the crossbearer sets up on the side in the frame, and the crossbearer bottom sets up the adjustment tank, and the adjustment tank internal rotation sets up horizontal lead screw, sets up the screw on the horizontal lead screw, and the screw bottom sets up the plummer, and horizontal lead screw one end is connected with driving motor's drive shaft through the shaft coupling, and driving motor sets up at crossbearer side surface, and plummer side surface sets up the pointer, and pointer one end extends to scale one side, and the scale setting is on crossbearer side surface.

Preferably, the driving motor is connected with a PLC controller through a connecting wire, and the PLC controller is arranged on one side surface of the rack.

Preferably, the PLC controller is connected with travel switch and electric putter through the connecting wire, and travel switch sets up in a frame side surface, and electric putter sets up on the plummer downside, and electric putter's piston rod one end sets up the brace table, and the brace table bottom sets up the cutter.

Preferably, one side of the bottom of the cross frame is fixedly connected with the frame through a reinforcing plate.

Preferably, the direction subassembly includes first riser and second riser, first riser and second riser symmetry set up at processing platform both sides surface, first riser side surface sets up first pneumatic cylinder, second riser side surface sets up the second pneumatic cylinder, the piston rod one end of first pneumatic cylinder sets up first locating plate, the piston rod one end of second pneumatic cylinder sets up the second locating plate, second locating plate side surface sets up the second pneumatic cylinder, the piston rod one end of second pneumatic cylinder sets up the second locating plate.

Preferably, first pneumatic cylinder and second pneumatic cylinder all are connected with the PLC controller through the connecting wire, and first pneumatic cylinder and second pneumatic cylinder specification are the same.

Preferably, a plurality of groups of first grooves are formed in the surface of one side of the first positioning plate at equal intervals, first guide rollers are arranged in the plurality of groups of first grooves in a rotating mode, a plurality of groups of second grooves are formed in the surface of one side of the second positioning plate at equal intervals, and second guide rollers are arranged in the plurality of groups of second grooves in a rotating mode.

Compared with the prior art, the above technical scheme of the utility model following profitable technological effect has:

1. the utility model discloses can carry out the precision measurement to blank cutting length, can satisfy the cutting of different length blanks, the simple operation is measured and cutting is efficient.

2. The utility model discloses can lead to the removal of blank, avoid the blank to remove the condition emergence that takes place the skew, can improve the accuracy nature of blank measurement and cutting.

Drawings

Fig. 1 is a schematic structural diagram of a blank size detection device for processing refractory bricks, which is provided by the utility model.

Fig. 2 is a schematic view of a sectional structure of a size adjusting assembly of the device for detecting the size of the blank for processing refractory bricks of the utility model.

Fig. 3 is an enlarged schematic view of a portion a in fig. 1.

Fig. 4 is a schematic view of a top-view cross-sectional structure of a guiding assembly of the device for detecting the size of the blank for processing refractory bricks of the present invention.

Reference numerals: 1. a size adjustment assembly; 2. a driving roller; 3. a guide assembly; 4. a machine base; 5. a processing table; 6. a PLC controller; 7. a frame; 101. a cross frame; 102. a transverse screw rod; 103. a nut; 104. an adjustment groove; 105. a drive motor; 106. a bearing table; 107. an electric push rod; 108. a cutter; 109. a support table; 110. a travel switch; 111. a graduated scale; 112. an indicator needle; 301. a first positioning plate; 302. a first hydraulic cylinder; 303. a first vertical plate; 304. a first groove; 305. a first guide roller; 306. a second guide roller; 307. a second groove; 308. a second hydraulic cylinder; 309. a second vertical plate; 310. and a second positioning plate.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

As shown in fig. 1-4, the present invention provides a blank size detection device for processing refractory bricks, which comprises a frame 4, a processing table 5 arranged on the top of the frame 4, a driving roller 2 rotatably arranged on one side of the processing table 5, and a frame 7 arranged on one side of the upper surface of the processing table 5, wherein the top of the frame 7 is provided with a size adjustment assembly 1, and the side of the processing table 5 is provided with a guide assembly 3;

size adjusting part 1 includes crossbearer 101, crossbearer 101 sets up on frame 7 side, crossbearer 101 bottom sets up adjustment tank 104, adjustment tank 104 internal rotation sets up horizontal lead screw 102, set up screw 103 on the horizontal lead screw 102, screw 103 bottom sets up plummer 106, horizontal lead screw 102 one end is connected with driving motor 105's drive shaft through the shaft coupling, driving motor 105 sets up at crossbearer 101 a side surface, plummer 106 a side surface sets up pointer 112, pointer 112 one end extends to scale 111 one side, scale 111 sets up at crossbearer 101 a side surface.

The utility model discloses in, at first move driving motor 105, driving motor 105 drives horizontal lead screw 102 and rotates, and horizontal lead screw 102 drives screw 103 and removes, and screw 103 drives plummer 106 and removes, and plummer 106 drives pointer 112 and removes on scale 111, when pointer 112 removes to blank cutting length sign, the shut down running driving motor 105.

In an alternative embodiment, the driving motor 105 is connected to the PLC controller 6 through a connection line, and the PLC controller 6 is disposed on a side surface of the housing 7.

Note that the operation of the drive motor 105 can be controlled.

In an alternative embodiment, the PLC controller 6 is connected to a travel switch 110 and an electric push rod 107 through connection lines, the travel switch 110 is disposed on a side surface of the frame 7, the electric push rod 107 is disposed on a lower side surface of the bearing platform 106, a supporting platform 109 is disposed at one end of a piston rod of the electric push rod 107, and a cutter 108 is disposed at a bottom of the supporting platform 109.

It should be noted that, the blank moves along the driving roller 2 in the production process, when the blank touches the travel switch 110, the PLC controller 6 controls the electric push rod 107 to operate, the electric push rod 107 drives the supporting platform 109 to move, the supporting platform 109 drives the cutter 108 to move downwards, and the cutter 108 cuts the blank.

In an alternative embodiment, the bottom side of the cross frame 101 is fixedly connected to the frame 7 through a reinforcing plate.

The firmness of the mounting of the cross member 101 can be improved.

In an alternative embodiment, the guiding assembly 3 includes a first vertical plate 303 and a second vertical plate 309, the first vertical plate 303 and the second vertical plate 309 are symmetrically disposed on two side surfaces of the processing table 5, a first hydraulic cylinder 302 is disposed on one side surface of the first vertical plate 303, a second hydraulic cylinder 308 is disposed on one side surface of the second vertical plate 309, a first positioning plate 301 is disposed at one end of a piston rod of the first hydraulic cylinder 302, a second positioning plate 310 is disposed at one end of a piston rod of the second hydraulic cylinder 308, a second hydraulic cylinder 308 is disposed on one side surface of the second positioning plate 310, a second positioning plate 310 is disposed at one end of a piston rod of the second hydraulic cylinder 308, the first hydraulic cylinder 302 and the second hydraulic cylinder 308 are both connected to the PLC controller 6 through a connecting wire, the first hydraulic cylinder 302 and the second hydraulic cylinder 308 have the same specification, a plurality of sets of first grooves 304 are equidistantly disposed on one side surface of the first positioning plate 301, a plurality of sets of first guiding rollers 305 are rotatably disposed in the plurality of sets of first grooves 304, a plurality of sets of second grooves 307 are equidistantly formed on one side surface of the second positioning plate 310, and the second guiding rollers 306 are rotatably disposed in the plurality of sets of second grooves 307.

It should be noted that, when the first hydraulic cylinder 302 and the second hydraulic cylinder 308 are operated, the first hydraulic cylinder 302 drives the first positioning plate 301 to move, the second hydraulic cylinder 308 drives the second positioning plate 310 to move, the first positioning plate 301 drives the first guiding roller 305 to move, the second positioning plate 310 drives the second guiding roller 306 to move, when the first guiding roller 305 and the second guiding roller 306 are attached to the blank, the first hydraulic cylinder 302 and the second hydraulic cylinder 308 are stopped to operate, the blank drives the first guiding roller 305 and the second guiding roller 306 to rotate during the moving process, and the first guiding roller 305 and the second guiding roller 306 guide the movement of the blank.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (7)

1. The device for detecting the size of the refractory brick processing blank is characterized by comprising a base (4), a processing table (5) arranged at the top of the base (4), a transmission roller (2) rotatably arranged on one side of the processing table (5) and a rack (7) arranged on one side of the upper surface of the processing table (5), wherein the top of the rack (7) is provided with a size adjusting component (1), and the side surface of the processing table (5) is provided with a guide component (3);

size adjusting part (1) includes crossbearer (101), crossbearer (101) set up on frame (7) side, crossbearer (101) bottom sets up adjustment tank (104), adjustment tank (104) internal rotation sets up horizontal lead screw (102), set up screw (103) on horizontal lead screw (102), screw (103) bottom sets up plummer (106), horizontal lead screw (102) one end is connected with driving motor (105)'s drive shaft through the shaft coupling, driving motor (105) set up at crossbearer (101) side surface, plummer (106) side surface sets up pointer (112), pointer (112) one end extends to scale (111) one side, scale (111) set up at crossbearer (101) side surface.

2. The apparatus for detecting the size of a refractory brick processing blank according to claim 1, wherein the drive motor (105) is connected to the PLC controller (6) through a connection line, and the PLC controller (6) is disposed on one side surface of the frame (7).

3. The device for detecting the size of the refractory brick processing blank according to claim 2, wherein the PLC (6) is connected with a travel switch (110) and an electric push rod (107) through connecting wires, the travel switch (110) is arranged on one side surface of the frame (7), the electric push rod (107) is arranged on the lower side surface of the bearing table (106), one end of a piston rod of the electric push rod (107) is provided with a supporting table (109), and the bottom of the supporting table (109) is provided with a cutter (108).

4. The apparatus for detecting the size of a refractory brick processing blank according to claim 3, wherein one side of the bottom of the cross frame (101) is fixedly connected with the frame (7) through a reinforcing plate.

5. The blank size detection device for processing the refractory bricks, according to claim 4, is characterized in that the guide assembly (3) comprises a first vertical plate (303) and a second vertical plate (309), the first vertical plate (303) and the second vertical plate (309) are symmetrically arranged on two side surfaces of the processing table (5), a first hydraulic cylinder (302) is arranged on one side surface of the first vertical plate (303), a second hydraulic cylinder (308) is arranged on one side surface of the second vertical plate (309), a first positioning plate (301) is arranged at one end of a piston rod of the first hydraulic cylinder (302), a second positioning plate (310) is arranged at one end of a piston rod of the second hydraulic cylinder (308), a second hydraulic cylinder (308) is arranged on one side surface of the second positioning plate (310), and a second positioning plate (310) is arranged at one end of a piston rod of the second hydraulic cylinder (308).

6. The apparatus for detecting the size of a material for manufacturing a refractory brick according to claim 5, wherein the first hydraulic cylinder (302) and the second hydraulic cylinder (308) are connected to the PLC controller (6) by connecting wires, and the first hydraulic cylinder (302) and the second hydraulic cylinder (308) have the same specification.

7. The apparatus as claimed in claim 6, wherein a plurality of sets of first grooves (304) are equidistantly formed on one side surface of the first positioning plate (301), the first guide rollers (305) are rotatably disposed in the plurality of sets of first grooves (304), a plurality of sets of second grooves (307) are equidistantly formed on one side surface of the second positioning plate (310), and the second guide rollers (306) are rotatably disposed in the plurality of sets of second grooves (307).

Images