CN118081997B - Stone cutter of multi-line down-pressing type - Google Patents

Abstract

The invention provides a multi-line down-pressing stone cutting machine which comprises a frame and a cutting device. Wherein, the space of placing of waste material is formed to the below in the frame, and cutting device is located the relative space of placing of frame and goes up and down. In the cutting device, rollers are arranged at the upper end and the lower end of the two sides in the lifting frame, diamond wires circularly bypass the rollers in the lifting frame, so that the diamond wires form a plurality of cutting lines which are arranged in parallel below the lifting frame, and the two ends of the diamond wires are respectively connected to the winding and unwinding cylinders arranged at the two sides outside the lifting frame. When the diamond wire winding and unwinding device works, one winding and unwinding cylinder rotates forward to pull the diamond wire to be wound, and the other winding and unwinding cylinder rotates reversely to release the diamond wire, so that each cutting wire below the lifting frame can move at high speed. When the lifting frame descends to the placing space of the frame, each cutting line can be pressed down simultaneously to saw cut the barren materials once to form a plurality of stones with the thickness equal to the distance between two adjacent cutting lines, and the one-time cutting mode is efficient.

Description

Stone cutter of multi-line down-pressing type

Technical Field

The invention relates to the structural field of cutting machines, in particular to a multi-line down-pressing stone cutting machine.

Background

In stone processing, the raw materials are generally cut by a wire saw. The structure of rope saw is mostly including removing the frame and cutting the rope, and wherein remove a plurality of leading wheels of frame setting, and remove frame open-ended both ends and all set up the leading wheel, and each leading wheel is walked around to the cutting rope, and the part that the cutting rope is located between the leading wheel at frame open-ended both ends is the saw cut section of cutting stone material, and this saw cut section is restricted by the leading wheel at frame open-ended both ends. During operation, the cutting motor fixed to the moving frame drives one of the guide wheels to rotate so as to drive the cutting rope to rotate, so that the cutting rope is driven to rotate at a high speed, and the sawing section is driven to move towards the raw materials through the movement of the moving frame so as to cut the raw materials.

However, the cutting mode can only cut one slot at a time, namely can only divide the raw material into two parts, and for the raw material which needs to be cut into a plurality of pieces of stone at one time, the raw material needs to be continuously cut for a plurality of times, so that the efficiency is too low.

Disclosure of Invention

Aiming at the defects of the background technology, the invention provides a multi-line down-pressing stone cutting machine.

The invention adopts the following technical scheme:

the utility model provides a multi-line down-pressing type stone material cutting machine, its characterized in that, this cutting machine includes frame and cutting device, the below in the frame forms the space of placing the barren material, cutting device is located in the frame is relative place the space goes up and down, cutting device includes:

the lifting frame is positioned in the rack and vertically lifts relative to the placing space, and an opening is formed below the lifting frame;

the winding and unwinding drums are driven by a winding and unwinding machine fixed outside the lifting frame, two sides outside the lifting frame are provided with rotating winding and unwinding drums, and the two winding and unwinding drums are respectively connected with two ends of the diamond wire;

The diamond wire circularly bypasses the rollers in the lifting frame, and the diamond wire sequentially bypasses the wire grooves in the rollers, so that the diamond wire forms a plurality of cutting lines which are arranged in parallel below the lifting frame;

The wire feeding module is arranged on two sides of the lifting frame and comprises a wire feeding seat, wire feeding wheels, photoelectric sensors and induction columns, the wire feeding wheels are connected to the wire feeding seat to rotate, the photoelectric sensors are provided with corresponding light emitting devices and receiving devices, the photoelectric sensors are fixed on two sides of the back of the wire feeding seat, the wire feeding seat is connected with the rotatable induction columns below the two photoelectric sensors, the diamond wire bypasses the wire feeding wheels and passes through the two induction columns to be connected to the winding and unwinding cylinders, the induction columns are used for fixing contact pieces on the back of the wire feeding seat, a plurality of through grooves are distributed on the edges of the surfaces of the contact pieces, and the upper ends of the contact pieces are located between the light emitting devices and the receiving devices of the photoelectric sensors;

When the diamond wire contacts the induction column and drives the contact piece to rotate, all through grooves of the contact piece sequentially rotate between the light emitting device and the receiving device, so that the photoelectric sensor is triggered to send a signal to the control system, and the control system controls the rotation speed of the winding and unwinding barrel or controls the movement speed of the wire holder according to the signal.

In one possible implementation, the induction column includes a rotating shaft, a rubber ring and the contact piece, the wire holder is fixed on a bearing seat, the rotating shaft passes through and is fixed on the bearing seat, one end of the rotating shaft is sleeved with the rubber ring, and the other end of the rotating shaft is fixed on the contact piece.

In one possible implementation manner, the wire routing module further comprises a moving mechanism, the moving mechanism is fixed on the lifting frame, the wire routing seat is connected to the moving mechanism, and the moving mechanism drives the wire routing seat to move.

In one possible implementation manner, tapered holes are formed in the end faces of two ends of the roller, connecting holes penetrating through the tapered holes are formed in the axial lead of the roller, the aperture of each tapered hole is gradually reduced from the outside of the roller to the inside of the roller, and the tapered holes and the connecting holes are penetrated with pull rods; bearing boxes are fixed on two sides of the lifting frame, connecting shafts are arranged on the two bearing boxes in a penetrating mode, a cone with the outer diameter gradually reduced is arranged at one end, facing the middle of the lifting frame, of the connecting shafts, a penetrating mounting hole is formed in the axis of one connecting shaft, and a threaded hole is formed in the end face of the cone of the other connecting shaft; one end of the pull rod is provided with a first stud, the first stud is matched with the threaded hole, the other end of the pull rod is provided with a pressing part with an enlarged outer diameter, and the first stud of the pull rod passes through the mounting hole and the connecting hole and is in spiral connection with the threaded hole, so that the pressing part pushes a connecting shaft provided with the mounting hole to a connecting shaft provided with the threaded hole, and the roller is pressed and fastened between the two connecting shafts.

In one possible implementation manner, the cutting device further comprises a guide module, wherein the guide module is arranged on two sides of the lifting frame, and two ends of the diamond wire are connected to one of the winding and unwinding cylinders after bypassing one of the guide modules; the guide module comprises a guide seat and a guide wheel, the guide wheel is connected to the guide seat to rotate, the guide seat is connected to the side edge of the lifting frame to horizontally move, and the diamond wire passes through the lifting frame from the roller above and then bypasses the guide wheel to be connected to the winding and unwinding cylinder.

In one possible implementation manner, the guide module further includes a fixing frame, an adjusting screw and a hand wheel, the fixing frame fixes two guide posts, the guide seat is adapted to pass through the two guide posts, the adjusting screw is disposed between the two guide posts, the adjusting screw is adapted to pass through the fixing frame in a spiral manner, and the hand wheel is connected to one end of the adjusting screw extending out of the fixing frame.

In one possible implementation manner, the cutting device further comprises tensioning modules, wherein the tensioning modules are arranged on two sides of the lifting frame, and two ends of the diamond wire are connected to one winding and unwinding cylinder after bypassing one tensioning module; the tensioning module comprises a tensioning frame, a tensioning motor, a swinging rod and a tensioning wheel, wherein the tensioning frame is fixed to the lifting frame, the tensioning motor is fixed to the tensioning frame, an output shaft of the tensioning motor is fixedly connected with one end of the swinging rod, the other end of the swinging rod is connected with the tensioning wheel, and the diamond wire is connected to the winding and unwinding cylinder after bypassing the tensioning wheel.

In a possible implementation manner, lifting mechanisms are arranged on two sides of the frame, each lifting mechanism comprises a lifting motor, a transmission shaft, a lifting screw and a nut seat, wherein in any one side of the frame, the lifting screws are connected in two upright posts of the frame, the output ends of the lifting motors are fixed to the transmission shafts, two ends of the transmission shafts are respectively connected with two lifting screw transmission sides of the frame, the transmission shafts drive the two lifting screws to synchronously rotate, the nut seats are respectively fixed on two sides outside the lifting frame, and the nut seats are respectively connected with two lifting screw adaptation screws.

In one possible implementation, the cutting machine further comprises a cooling device, the cooling device comprises a plurality of water storage tanks arranged on the upper surface of the lifting frame and a water guide pipe connected to the water storage tanks, water outlets are distributed on the bottom surface of each water storage tank, each water outlet corresponds to the diamond wire, and the water guide pipe introduces a water source into each water storage tank.

In one possible implementation manner, the cutting machine further comprises a ferry vehicle, wherein the ferry vehicle is used for placing the raw materials, baffles are arranged on two sides of the ferry vehicle, and after the ferry vehicle moves to the placing space, the two baffles are respectively positioned at two ends of the cutting line arrangement direction.

As can be seen from the above description of the structure of the present invention, compared with the prior art, the present invention has the following advantages: when the diamond wire winding and unwinding device works, one winding and unwinding cylinder rotates forward to pull the diamond wire to be wound, and the other winding and unwinding cylinder rotates reversely to release the diamond wire, so that the diamond wire at each cutting line position can move at high speed. When the lifting frame descends to the placing space of the frame, each cutting line can be simultaneously pressed down to saw the raw material at one time to form a plurality of pieces of stone with the thickness equal to the interval between two adjacent cutting lines, and the one-time cutting mode is efficient for the raw material which needs to be cut to form a plurality of pieces of stone.

And in the cutting process, when the two ends of the wire-walking seat move reciprocally relative to the winding and unwinding cylinder, and when the moving speed of the two ends of the wire-walking seat is inconsistent with the moving speed of the wire-walking seat, the wire-walking seat contacts the sensing column and drives the rotating shaft to rotate, so that the contact piece rotates between the light emitting device and the receiving device of the photoelectric sensor to shield the receiving device from receiving the light emitted by the light emitting device, the photoelectric sensor obtains the signal and sends the signal to the control system, and the control system controls the winding and unwinding cylinder to rotate according to the signal so as to wind or unwind the wire, so that the wire-walking seat can drive the wire-walking seat to stably wind and unwind when the winding and unwinding cylinder rotates.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a front view of the present invention with the cut line depressed into the block in the holding space.

Fig. 3 is a schematic perspective view of the frame.

Fig. 4 is an enlarged schematic view at a in fig. 3.

Fig. 5 is a schematic perspective view of a cutting device.

Fig. 6 is an enlarged schematic view at B in fig. 5.

Fig. 7 is a schematic view of an embodiment after enlarging the distance between two adjacent cutting lines.

Fig. 8 is a schematic cross-sectional view of a crane connecting roller.

Fig. 9 is an enlarged schematic view at C in fig. 8.

Fig. 10 is an enlarged schematic view of fig. 8 at D.

FIG. 11 is a schematic sectional view of a roll.

Fig. 12 is a schematic perspective view of the pull rod.

Fig. 13 is a schematic structural view of a winding and unwinding drum, a guiding module, a tensioning module and a wiring module, which are arranged on the right side of the lifting frame in fig. 5.

Fig. 14 is a schematic perspective view of a guide module.

Fig. 15 is a schematic perspective view of a tensioning module.

Fig. 16 is a schematic perspective view of a wiring module.

Fig. 17 is a schematic perspective view of the backside view under the trace seat.

Fig. 18 is a schematic perspective view of a connecting sensing post of a trace holder (one of the sensing posts is in cross section).

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail with reference to the accompanying drawings.

In the present application, directional terms such as "upper", "lower" and the like are defined with respect to the orientation in which the components are schematically positioned in the drawings, and it should be understood that these directional terms are relative concepts, which are used for description and clarity with respect thereto, and which may be correspondingly varied according to the variation in the orientation in which the components are positioned in the drawings.

The invention discloses a multi-line down-pressing stone cutting machine, which comprises a frame 1, a cutting device 2, a cooling device and a ferry vehicle 4, as shown in figures 1 and 2. Wherein, the frame 1 forms a gantry structure, and the frame 1 is fixed on the ground, in particular, the foundation can be excavated on the ground, and then the upright posts 11 at two sides of the frame 1 are buried in the foundation, so that the frame 1 is fixed on the ground. A placing space 101 for placing the raw materials 5 is formed below the frame 1, and the cutting device 2 is located in the frame 1 and is lifted relative to the placing space 101. The ferry vehicle 4 is used for placing the raw materials 5, after the ferry vehicle 4 conveys the raw materials 5 to the placement space 101, the cutting device 2 is pressed down to cut the raw materials 5, and the cooling device cools the cutting device 2 in the cutting process.

As shown in fig. 5 to 7, the cutting device 2 includes a diamond wire 21, a lifting frame 22, a winding and unwinding drum 23, a drum 24, a guide module 25, a tensioning module 26, and a wire routing module 27. Wherein the lower side of the lifting frame 22 is formed to be opened, and the lifting frame 22 is vertically lifted with respect to the placement space 101 in the frame 1. Both sides outside the lifting frame 22 are provided with a winding and unwinding cylinder 23, a guiding module 25, a tensioning module 26 and a wiring module 27. Rollers 24 are arranged at the upper end and the lower end of the two sides in the lifting frame 22, namely, the rollers 24 are arranged at four corners in the lifting frame 22. The lifting frame 22 is also provided with roller motors 241 at positions corresponding to the rollers 24, and the output ends of the roller motors 241 are connected to the rollers 24, so that the roller motors 241 can drive the rollers 24 to rotate. Referring again to fig. 14, the annular surface of the roller 24 is provided with a plurality of wire grooves 2403, the diamond wire 21 circularly bypasses each roller 24 in the lifting frame 22, and the diamond wire 21 sequentially bypasses each wire groove 2403 in each roller 24, so that the diamond wire 21 forms a plurality of cutting lines 211 which are arranged in parallel below the lifting frame 22, and when the diamond wire 21 moves at a high speed, each cutting line 211 is used for cutting the raw material 5.

Preferably, as shown in fig. 2 and 8, the roller 24 is sleeved with a rubber sleeve 242, the rubber sleeve 242 is a colloid integrally cast and fixed on the outer surface of the roller 24, and a plurality of wire slots 2403 are distributed on the annular surface of the rubber sleeve 242 along the extending direction of the axial lead of the rubber sleeve. The friction force between the roller 24 and the diamond wire 21 can be increased through the connection of the rubber sleeve 242, slipping is avoided, and the trend of the diamond wire 21 is limited, so that the two adjacent cutting lines 211 form a fixed interval. In addition, when the use is up to a certain period or the interval between two adjacent cutting lines 211 needs to be replaced, the roller 24 can be removed to replace the rubber sleeve 242 with a different interval between the line grooves 2403. It should be noted that the rubber sleeve 242 with different pitches of the wire grooves 2403 can be used for cutting the block 5 into stone materials with different thicknesses.

Referring again to fig. 8 to 10, the structure in which the roller 24 is coupled to the elevation frame 22 may be installed and fixed through the bearing housing 15, the coupling shaft 16 and the tie rod 17. Wherein, bearing boxes 15 are fixed at both ends of the lifting frame 22, connecting shafts 16 are arranged in the two bearing boxes 15 in a penetrating way, and the connecting shafts 16 penetrate through bearings arranged in the bearing boxes 15, so that the connecting shafts 16 rotate and axially move relative to the bearing boxes 15. The roller 24 is arranged between the connecting shafts 16 of the two bearing boxes 15, and the connecting shafts 16 are connected and tensioned through the pull rod 17 so as to press and fix the roller 24 between the connecting shafts 16. In addition, the lifting frame 22 is also fixed with a roller motor 241, wherein one end of a connecting shaft 16 far away from the middle of the lifting frame 22 penetrates out of the bearing box 15 and is connected with an output shaft of the roller motor 241 through a coupling, so that the roller motor 241 drives the connecting shaft 16 to rotate and simultaneously drives the roller 24 to rotate.

As shown in fig. 11, a connecting hole 2402 is formed on the axial line of the roller 24, tapered holes 2401 are formed on the end surfaces of the two ends of the roller 24, the aperture of the tapered holes 2401 is gradually reduced from the outside of the roller 24 to the inside of the roller 24, the tapered holes 2401 are correspondingly communicated with the connecting hole 2402, and the pull rod 17 passes through the tapered holes 2401 and the connecting hole 2402.

With continued reference to fig. 8 and 9, the ends of the connecting shafts 16 toward the middle of the elevator frame 22 are each provided with a taper 161 of gradually decreasing outer diameter. One connecting shaft 16 is provided with a penetrating mounting hole 1601 on the axial lead, the other connecting shaft 16 is provided with a threaded hole 1602 on the end face of the cone 161, and the connecting shaft 16 provided with the threaded hole 1602 is used for connecting the roller motor 241, that is, one end of the connecting shaft 16 far away from the threaded hole 1602 penetrates out of the bearing box 15 to be in transmission connection with the output shaft of the roller motor 241. Further, the end surface of the connecting shaft 16, on which one end of the cone 161 is provided, is provided with a protruding limit portion 164, and the inner end surface of the roller 24, on which the tapered hole 2401 is provided, is provided with a recessed limit groove 2404. When the cone 161 of the connecting shaft 16 is inserted into the cone hole 2401 of the roller 24, the limiting part 164 is adapted to be inserted into the limiting groove 2404, so that the connecting shaft 16 and the roller 24 automatically form a circumferentially fixed connecting structure, and the roller 24 can be driven to rotate when the connecting shaft 16 rotates.

As shown in fig. 12, a first stud 171 is provided at one end of the pull rod 17, the first stud 171 is fitted into a threaded hole 1602, and a pressing portion 173 having an enlarged outer diameter is provided at the other end of the pull rod 17. Preferably, the other end of the pull rod 17 opposite to the first stud 171 is a second stud 172, and the second stud 172 is adapted to be connected with a nut, namely a pressing portion 173. Further, the tie rod 17 is provided with a hexagonal prism 174 at an end surface of the pressing portion 173, and the hexagonal prism 174 is used for a hexagonal wrench to be engaged to turn the tie rod 17.

After the above structure is adopted, when the roller 24 is installed, the roller 24 is arranged between the two connecting shafts 16, the connecting shafts 16 with the installation holes 1601 are pushed towards the middle of the lifting frame 22, so as to push the roller 24 to move towards the connecting shafts 16 with the installation holes 1602, the cones 161 of the two connecting shafts 16 are respectively matched with the conical holes 2401 embedded at the two ends of the roller 24, so as to clamp the roller 24, then the first studs 171 of the pull rod 17 penetrate through the installation holes 1601 of the connecting shafts 16 and the connecting holes 2402 of the roller 24 and correspond to the threaded holes 1602 of the other connecting shafts 16, the pull rod 17 is rotated to screw the first studs 171 into the threaded holes 1602 and tightly screw the first studs 171, then the nuts penetrate through the hexagonal prisms 174 and are in screwed connection with the second studs 172, so that the nuts are pressed towards the outer side surface of the bearing box 15, and the connecting shafts 16 with the installation holes 1601 are pushed towards the connecting shafts 16 with the threaded holes 1602, so that the cones 161 of the two connecting shafts 16 are mutually close to each other, the cones 161 of the two connecting shafts 16 are gradually pressed into the conical holes 2401 at the two ends of the roller 24, the connecting shafts 16 are utilized, the connecting shafts 16 are pressed into the conical holes 2401 at the two ends, so that the connecting shafts 16 are clamped and the connecting shafts 16 are fixed, the connecting shafts 16 are screwed into the threaded holes 1602, and the roller 24 are screwed, and the roller 21 is driven to move at a high speed, and the roller 24 is driven to rotate. And during this installation, the insertion of cone 161 into tapered bore 2401 creates a guiding action that pushes the two connecting shafts 16 to be coaxial with the rollers 24 without having to recalibrate the parallelism of the rollers.

Preferably, after the nut and the tie rod 17 are screwed to the tightening portion 173 fixed with respect to the tie rod 17, the first stud 171 of the tie rod 17 is screwed to the tightening portion through the mounting hole 1601 of the connecting shaft 16 and the connecting hole 2402 of the roller 24 and the threaded hole 1602 of the other connecting shaft 16, and the nut is pressed against the bearing housing 15 to push the connecting shaft 16 provided with the mounting hole 1601 toward the connecting shaft 16 provided with the threaded hole 1602.

When the roller 24 is detached, the first stud 171 of the pull rod 17 is reversely screwed out of the threaded hole 1602 of the connecting shaft 16, the pull rod 17 is taken out of the connecting hole 2402 of the roller 24 and the mounting hole 1601 of the connecting shaft 16, the connecting shaft 16 provided with the mounting hole 1601 is pulled out of the lifting frame 22, and the cone 161 of the connecting shaft 16 is separated from the cone hole 2401 of the roller 24, so that the roller 24 can be detached.

According to the roller 24 installing and detaching mode, the roller 24 connecting structure does not need to fixedly connect the roller 24 with the bearing box 15, can be connected and fixed only by screwing the pull rod 17, and can be detached by unscrewing and pulling the pull rod 17, so that the assembly and disassembly are very convenient, and the efficiency of installing and maintaining the wire saw machine and replacing the rubber sleeve 242 is improved.

The lifting manner of the lifting frame 22 can be that the sliding rails 285 are fixed on two sides of the upright post 11 of the frame 1, the sliding rails 285 are matched with the sliding blocks 286, and the outer side surface of the lifting frame 22 is fixed to the sliding blocks 286, so that the lifting frame 22 can only vertically lift relative to the frame 1 along the sliding rails 285. In addition, the lifting control manner of the lifting frame 22 may be driven by lifting mechanisms disposed on two sides of the frame 1 shown in fig. 3 and 4, where the lifting mechanisms include a lifting motor 281, a transmission shaft 282, a lifting screw 283 and a nut seat 284, in any side of the frame 1, the lifting screw 283 is connected to a position between two sliding rails 285 in the upright post 11 of the frame 1, the nut seats 284 are fixed on two sides outside the lifting frame 22, and the two nut seats 284 are respectively and spirally connected to the two lifting screws 283 in an adaptive manner. The output end of the lifting motor 281 is fixedly provided with a transmission shaft 282, two ends of the transmission shaft 282 are respectively connected with two lifting screw rods 283 on the side edge of the frame 1 through a gear box to form transmission connection, so that the transmission shaft 282 drives the two lifting screw rods 283 to synchronously rotate, and the nut seat 284 is driven to lift, so that the lifting motor 281 of the two lifting mechanisms drives the lifting frame 22 to lift.

Preferably, a platform 12 is further provided on the periphery of the frame 1, and a ladder stand 13 is further provided on one side of the platform 12. When the cutting device 2 needs to be overhauled, a worker can climb the platform 12 through the ladder 13 to overhaul the cutting device 2 which rises to the placing space 101.

With continued reference to fig. 2 and 7, the ferry vehicle 4 is used for placing the waste materials 5, the two sides of the ferry vehicle 4 are provided with the baffle plates 41, and when the ferry vehicle 4 moves to the placement space 101, the two baffle plates 41 are respectively located at two ends of the arrangement direction of the cutting lines 211. Specifically, when the ferry vehicle 4 moves to the placement space 101, the lifting frame 22 descends to drive the diamond wires 21 to press down, so that each cutting wire 211 presses down to saw the raw material 5, and the raw material 5 is cut at one time to form a plurality of stones with the thickness equal to the distance between two adjacent cutting wires. And after the cutting is completed, the two baffles 41 can block the poured stone, so that the cut stone is prevented from being collapsed and bruised. Referring to fig. 1 again, the frame 1 is integrally provided with four vertical upright posts 11 for supporting and forming, gaps formed between two adjacent upright posts 11 can be paved with a rail 42 for moving the ferry vehicle, so that the ferry vehicle 4 can move into the placing space 101, a mode that the ferry vehicle 4 moves into the placing space 101 in multiple directions for conveying the raw materials 5 is formed, the processing progress of the raw materials 5 is promoted, movable curtains or cabinet doors 14 shown in fig. 3 can be arranged between two adjacent upright posts 11 for shielding, and therefore a relatively closed space is formed inside the placing space 101, and dust generated by processing is prevented from drifting outwards.

As shown in fig. 5 and 6, the cooling device comprises a plurality of water storage tanks 31 arranged on the upper surface of the lifting frame 22 and water guide pipes (not shown) connected to the water storage tanks 31, wherein water outlet holes 301 are distributed on the bottom surface of each water storage tank 31, each water outlet hole 301 corresponds to a diamond wire 21, the water guide pipes guide water sources into each water storage tank 31, a specific water guide pipe can be a hose, and one end of each water guide pipe is connected to a water source (such as municipal water source), and in the structure, the water guide pipes are utilized to guide the water sources into the water storage tanks 31 so that water flows downwards from the water outlet holes 301 to the diamond wire 21, and the diamond wire 21 cut by high-speed operation is cooled. Preferably, a cover plate (not shown) may be further covered over each water storage tank 31 so that a closed space is formed inside the water storage tank 31, so that water can only fall from each water outlet 301 to the diamond wire 21 after being poured into the water storage tank 31.

As shown in fig. 5, the two sides outside the lifting frame 22 are provided with the winding and unwinding drums 23, and the winding and unwinding drums 23 are driven by the winding and unwinding motor 231 fixed outside the lifting frame 22, and the two winding and unwinding drums 23 are respectively connected with two ends of the diamond wire 21 after bypassing each roller 24, namely, two ends of the diamond wire 21 are respectively connected to the two winding and unwinding drums 23 after penetrating out of the lifting frame 22. In the two winding and unwinding drums 23, when one winding and unwinding drum 23 rotates forward to pull the diamond wire 21 to wind, the other winding and unwinding drum 23 rotates reversely to release the diamond wire 21, so that each cutting line 211 below the lifting frame 22 can move at high speed; thereafter, the other housing tube 23 is rotated forward and the housing tube 23 rotated forward is rotated backward, so that the diamond wire 21 at the position of each cutting line 211 can be moved at a high speed in the reverse direction. It can be seen that the process of reciprocally moving the diamond wire 21 at a high speed in the directions of both sides of the lifter 22 can be formed by alternately reciprocally rotating the two winding and unwinding drums 23, so that each cutting wire 211 reciprocally moves at a high speed in the directions of both sides of the lifter 22.

As shown in fig. 5 and 13, guide modules 25 are provided at both sides outside the elevation frame 22, and in both sides of the elevation frame 22, the ends of the diamond wire 21 are passed out from the upper roller 24, and then connected to the winding and unwinding drum 23 by bypassing the guide modules 25. Referring again to fig. 14, the guide module 25 includes a holder 251, guide wheels 252, an adjustment screw 253, a guide seat 254, and a hand wheel 255. Wherein, the fixing frame 251 is fixed at the side outside the lifting frame 22, the fixing frame 251 fixes two guide posts 256, and the guide seat 254 is adapted to pass through the two guide posts 256 to limit the guide seat 254 to be connected at the side of the lifting frame 22 to horizontally move. The guide wheel 252 is connected to the guide base 254 for rotation, and the diamond wire 21 passes through the lifting frame 22, bypasses the guide wheel 252 and is connected to the winding and unwinding drum 23.

With continued reference to fig. 14, the adjustment screw 253 is disposed between the two guide posts 256, and the adjustment screw 253 is adapted to be threaded through the guide seat 254, with the hand wheel 255 attached to the end of the adjustment screw 253 that extends beyond the mount 251. In operation, the hand wheel 255 is rotated to drive the adjusting screw 253 to rotate so as to enable the guide seat 254 to move, thereby driving the guide wheel 252 to move so as to adjust the position of the guide wheel 252 and realize the adjustment of the position of the diamond wire 21 penetrating out of the lifting frame 22. The purpose of the position of the diamond wire 21 passing out of the lifting frame 22 is that, in the rubber sleeves 242 with different wire grooves 2403, the positions of the first wire grooves 2403 at two ends of the roller 24 relative to the lifting frame 22 may be different according to the arrangement and distribution of the wire grooves 2403, so after the rubber sleeves 242 with different wire groove 2403 intervals are replaced, the positions of the guide wheels 252 are adjusted to be aligned with the wire grooves 2403 of the end part of the roller 24, which winds out of the diamond wire 21, of the upper roller 24, and then passes out of the lifting frame 22, so that the diamond wire 21 bypasses the guide wheels 252 straightly when passing out of the lifting frame 22 after bypassing the wire grooves 2403 of the roller 24, and the corners of the diamond wire 21 are prevented from being directly ground across the wire grooves 2403 by obliquely extending to the guide wheels 252 after winding around the wire grooves 2403 of the roller 24.

As shown in fig. 5 and 13, tension modules 26 are provided on both sides outside the lifting frame 22, and in both sides of the lifting frame 22, the diamond wire 21 is connected to a take-up and pay-off drum 23 after bypassing one tension module 26. Referring again to fig. 15, the tensioning module 26 includes a tensioning frame 261, a tensioning motor 262, and a swing link 263 and a tensioning wheel 264, wherein the tensioning frame 261 is fixed to the outer side surface of the lifting frame 22, the tensioning motor 262 is fixed to the tensioning frame 261, and an output shaft of the tensioning motor 262 is fixedly connected to one end of the swing link 263, the other end of the swing link 263 is connected to the tensioning wheel 264, and the diamond wire 21 wound around the guiding wheel 252 is connected to the winding and unwinding drum 23 after being wound around the tensioning wheel 264. When the diamond wire 21 is in operation, the tension motor 262 is controlled to rotate to drive the swinging rod 263 to swing, so that the tension wheel 264 is driven to swing, and the tightness of the diamond wire 21 is controlled.

As shown in fig. 5 and 13, the wire-laying modules 27 are provided on both sides of the lifting frame 22, and both ends of the diamond wire 21 are connected to a winding drum 23 after bypassing one wire-laying module 27. Referring again to fig. 16-18, the cabling module 27 includes a cabling housing 271, cabling wheels 272, photosensors 273 and sensing posts 274, and a movement mechanism 275. The moving mechanism 275 is fixed outside the lifting frame 22, the wiring seat 271 is connected to the moving mechanism 275, and the moving mechanism 275 drives the wiring seat 271 to move, and the moving mechanism 275 specifically is a structure in which a motor drives a ball screw to rotate so as to drive the wiring seat 271 to move. In addition, the wire wheel 272 is connected to the wire seat 271 for rotation, so that the moving mechanism 275 can drive the wire wheel 272 to move. The diamond wire 21 bypasses the wire wheel 272 and passes through the rubber rings 2743 of the two induction posts 274, and then is connected to the winding and unwinding drum 23. In this structure, when the wire 21 is wound around the winding and unwinding drum 23 by moving the wire holder 271 and the wire wheel 272 with respect to both ends of the winding and unwinding drum 23, the wire 21 is spirally wound around the winding and unwinding drum 23 one by one, and when the winding and unwinding drum 23 releases the wire 21, the wire 21 is spirally released with respect to both ends of the winding and unwinding drum 23.

The photosensor 273 has a corresponding light emitting device 2731 and receiving device 2732, i.e., the photosensor 273 is an infrared photosensor of U-shaped structure.

Both sides of the back of the wiring seat 271 are fixed with the photoelectric sensors 273, and the wiring seat 271 is connected with rotatable sensing posts 274 below the two photoelectric sensors 273. As shown in fig. 18, the sensing post 274 includes a rotating shaft 2741, a contact plate 2742, and a rubber ring 2743, wherein the rubber ring 2743 is sleeved outside one end of the rotating shaft 2741, and the contact plate 2742 is fixed at the other end of the rotating shaft 2741. The wiring seat 271 fixes the bearing seat, and the middle portion of the rotating shaft 2741 passes through and is fixed to the bearing seat to restrict the sensing post 274 from rotating only relative to the wiring seat 271 as a whole, so that the contact piece 2742 can rotate only relative to the photoelectric sensor 273. In addition, a plurality of through grooves 2744 are distributed on the edge of the surface of the contact piece 2742, and the contact piece 2742 is located on the back surface of the wiring seat 271, and the upper end of the contact piece 2742 is located between the light emitting device 2731 and the receiving device 2732 of the photoelectric sensor 273. When the sensing post 274 rotates until the through groove 2744 of the contact plate 2742 is located between the light emitting device 2731 and the receiving device 2732, the receiving device 2732 can receive infrared light emitted by the light emitting device 2731, and when the contact plate 2742 rotates until the through groove 2744 does not correspond to the light emitting device 2731, the infrared light emitted by the light emitting device 2731 is not shielded by the portion of the contact plate 2742 where the through groove 2744 is arranged. And as the sensing post 274 and the contact plate 2742 rotate, the through grooves 2744 of the contact plate 2742 sequentially rotate between the light emitting device 2731 and the receiving device 2732, so that the receiving device 2732 can intermittently receive infrared light emitted by the light emitting device 2731, that is, the receiving device 2732 alternately receives and does not receive infrared light, and the photoelectric sensor 273 generates a triggered signal according to the infrared light.

With the above structure, when the winding and unwinding drum 23 rotates to and from the diamond wire 21, the wire seat 271 reciprocates relative to the two ends of the winding and unwinding drum 23, and when the speed of movement of the two ends of the winding and unwinding drum 23 is inconsistent with the speed of movement of the wire seat 271 during winding and unwinding of the diamond wire 21, the diamond wire 21 contacts the sensing column 274 and drives the rotating shaft 2741 to rotate, the contact piece 2742 is driven to rotate between the light emitting device 2731 and the receiving device 2732 of the photoelectric sensor 273, the receiving device 2732 alternately receives and does not receive infrared light to generate a signal triggered by the photoelectric sensor 273, the photoelectric sensor 273 obtains the signal and sends the signal to the control system, and the control system controls the winding and unwinding drum 23 to stably operate according to the signal, for example, the control system controls the rotating speed of the winding and unwinding drum 23 to be accelerated, the speed of movement of the two ends of the winding and unwinding drum 23 to be consistent with the speed of movement of the wire seat 271, or controls the moving speed of the wire seat 2732 to be slow to be consistent with the speed of movement of the two ends of the winding and unwinding drum 23 when the winding and unwinding drum 21 is wound and unwinding drum 23. Therefore, the sensing manner of the sensing post 274 and the photoelectric sensor 273 can guide the diamond wire 21 to stably retract and move at two ends of the relative retraction barrel 23, so as to avoid the diamond wire 21 from being broken due to the too fast movement of the wire wheel 272 relative to the retraction barrel 23. It should be noted that the control system may be a PLC control system, which is used to control the operation of the execution elements such as the motors.

As described above, in the cutting device 2 of the present invention, the diamond wire 21 circularly passes through the rollers 24 provided at both upper and lower ends of the inner side of the lifting frame 22 in the lifting frame 22, so that the diamond wire 21 forms a plurality of cutting lines 211 arranged in parallel below the lifting frame 22. The guiding module 25 guides the end of the diamond wire 21 to the outside of the lifting frame 22, and sequentially bypasses the tensioning wheel 264 of the tensioning module 26 and the wire feeding wheel 272 of the wire feeding module 27 to the winding and unwinding drum 23. When the diamond wire winding and unwinding device works, one winding and unwinding cylinder 23 rotates forward to pull the diamond wire 21 to wind, and the other winding and unwinding cylinder 23 rotates reversely to release the diamond wire 21, so that the diamond wire 21 can move at a high speed, and each cutting line 211 below the lifting frame 22 moves at a high speed. When the lifting frame 22 descends to the placing space 101 of the frame 1, each cutting line 211 can be simultaneously pressed down to saw cut the raw material 5 once to form a plurality of pieces of stone with the thickness equal to the interval between two adjacent cutting lines, and the one-time cutting mode is more efficient for the raw material 5 needing to be cut to form a plurality of pieces of stone.

The foregoing is merely illustrative of specific embodiments of the present invention, but the design concept of the present invention is not limited thereto, and any insubstantial modification of the present invention by using the design concept shall fall within the scope of the present invention.

Claims (8)

1. The utility model provides a multi-line down-pressing type stone material cutting machine, its characterized in that, this cutting machine includes frame and cutting device, the below in the frame forms the space of placing the barren material, cutting device is located in the frame is relative place the space goes up and down, cutting device includes:

the lifting frame is positioned in the rack and vertically lifts relative to the placing space, and an opening is formed below the lifting frame;

the winding and unwinding drums are driven by a winding and unwinding machine fixed outside the lifting frame, two sides outside the lifting frame are provided with rotating winding and unwinding drums, and the two winding and unwinding drums are respectively connected with two ends of the diamond wire;

the diamond wire circularly bypasses the rollers in the lifting frame, and the diamond wire sequentially bypasses the wire grooves in the rollers, so that the diamond wire forms a plurality of cutting lines which are arranged in parallel below the lifting frame; the end surfaces of the two ends of the roller are provided with conical holes, the axial lead of the roller is provided with connecting holes penetrating through the two conical holes, the aperture of each conical hole is gradually reduced from the outside of the roller to the inside of the roller, and the conical holes and the connecting holes are penetrated with pull rods; bearing boxes are fixed on two sides of the lifting frame, connecting shafts are arranged on the two bearing boxes in a penetrating mode, a cone with the outer diameter gradually reduced is arranged at one end, facing the middle of the lifting frame, of the connecting shafts, a penetrating mounting hole is formed in the axis line of one connecting shaft, a threaded hole is formed in the end face of the cone, and one end, far away from the threaded hole, of the connecting shaft with the threaded hole penetrates out of the bearing box to be in transmission connection with an output shaft of the roller motor; the end face of the connecting shaft, which is provided with one end of the cone, is provided with a protruding limiting part, and the end face of the roller, which is provided with the inner part of the cone hole, is provided with a recessed limiting groove; one end of the pull rod is provided with a first stud which is matched with the threaded hole, the other end of the pull rod is provided with a pressing part with an enlarged outer diameter, the first stud of the pull rod passes through the mounting hole and the connecting hole and is in spiral connection with the threaded hole, the pressing part pushes the connecting shaft provided with the mounting hole to the connecting shaft provided with the threaded hole, the cone of the connecting shaft is inserted into the conical hole of the roller, so that the roller is pressed and fixed between the two connecting shafts, and the limiting part is matched and inserted into the limiting groove;

The wire feeding module is arranged on two sides of the lifting frame and comprises a wire feeding seat, a wire feeding wheel, a photoelectric sensor and an induction column, the wire feeding wheel is connected to the wire feeding seat for rotation, the photoelectric sensor is provided with a corresponding light emitting device and a corresponding receiving device, the photoelectric sensor is fixed on two sides of the back of the wire feeding seat, the wire feeding seat is connected with the rotatable induction column below the two photoelectric sensors, the diamond wire bypasses the wire feeding wheel and passes through the two induction columns and then is connected to the winding and unwinding cylinder, the induction column comprises a rotating shaft, a rubber ring and a contact piece, the rotating shaft passes through and is fixed to the bearing seat, one end of the rotating shaft is sleeved with the rubber ring, the other end of the rotating shaft is fixed with the contact piece, the contact piece is fixed at the back position of the wire feeding seat, the edges of the surface of the contact piece are distributed with a plurality of through grooves, and the upper ends of the contact piece are positioned between the light emitting device and the receiving device of the photoelectric sensor;

When the diamond wire contacts the induction column and drives the contact piece to rotate, all through grooves of the contact piece sequentially rotate between the light emitting device and the receiving device, so that the photoelectric sensor is triggered to send a signal to the control system, and the control system controls the rotation speed of the winding and unwinding barrel or controls the movement speed of the wire holder according to the signal.

2. The multi-wire down-pressing stone cutter of claim 1, wherein the wire-moving module further comprises a moving mechanism, the moving mechanism is fixed on the lifting frame, the wire-moving seat is connected to the moving mechanism, and the moving mechanism drives the wire-moving seat to move.

3. The multi-line down-pressing stone cutter according to claim 1, wherein the cutting device further comprises guide modules, the guide modules are arranged on both sides of the lifting frame, and both ends of the diamond wire are connected to a winding and unwinding cylinder after bypassing one guide module; the guide module comprises a guide seat and a guide wheel, the guide wheel is connected to the guide seat to rotate, the guide seat is connected to the side edge of the lifting frame to horizontally move, and the diamond wire passes through the lifting frame from the roller above and then bypasses the guide wheel to be connected to the winding and unwinding cylinder.

4. A multi-line down-pressing stone cutter according to claim 3, wherein the guide module further comprises a fixing frame, an adjusting screw and a hand wheel, wherein the fixing frame fixes two guide posts, the guide seat is adapted to pass through the two guide posts, the adjusting screw is arranged between the two guide posts, the adjusting screw is adapted to pass through the fixing frame in a spiral manner, and the hand wheel is connected to one end of the adjusting screw extending out of the fixing frame.

5. The multi-line down-pressing stone cutter according to claim 1, wherein the cutting device further comprises tensioning modules, wherein the tensioning modules are arranged on two sides of the lifting frame, and two ends of the diamond wire are connected to a winding and unwinding cylinder after bypassing one tensioning module; the tensioning module comprises a tensioning frame, a tensioning motor, a swinging rod and a tensioning wheel, wherein the tensioning frame is fixed to the lifting frame, the tensioning motor is fixed to the tensioning frame, an output shaft of the tensioning motor is fixedly connected with one end of the swinging rod, the other end of the swinging rod is connected with the tensioning wheel, and the diamond wire is connected to the winding and unwinding cylinder after bypassing the tensioning wheel.

6. The multi-line down-pressing stone cutter according to claim 1, wherein lifting mechanisms are arranged on two sides of the frame, each lifting mechanism comprises a lifting motor, a transmission shaft, a lifting screw and a nut seat, the lifting screw is connected in two upright posts of the frame in any side of the frame, the transmission shafts are fixed at the output ends of the lifting motors, two ends of the transmission shafts are respectively in transmission connection with two lifting screws on the side edges of the frame, the transmission shafts drive the two lifting screws to synchronously rotate, the nut seats are fixed on two sides outside the lifting frame, and the two nut seats are respectively in adaptive screw connection with the two lifting screws.

7. The multi-line down-pressure stone cutter according to claim 1, further comprising a cooling device, wherein the cooling device comprises a plurality of water storage tanks arranged on the upper surface of the lifting frame and a water guide pipe connected to the water storage tanks, water outlets are distributed on the bottom surface of each water storage tank, each water outlet corresponds to the diamond wire, and the water guide pipe guides a water source into each water storage tank.

8. The multi-line down-pressing stone cutter according to claim 1, further comprising a ferry vehicle, wherein the ferry vehicle is used for placing raw materials, two sides of the ferry vehicle are provided with baffle plates, and when the ferry vehicle moves to the placing space, the two baffle plates are respectively positioned at two ends of the arrangement direction of the cutting lines.