CN112339133A

CN112339133A - Building construction method

Info

Publication number: CN112339133A
Application number: CN202011171099.3A
Authority: CN
Inventors: 陈之现; 马敬磊; 张海英
Original assignee: Ningbo Intelligent Machinery Co ltd
Current assignee: Ningbo Intelligent Machinery Co ltd
Priority date: 2020-10-28
Filing date: 2020-10-28
Publication date: 2021-02-09

Abstract

The invention discloses a building construction method, which comprises the following steps that firstly, a frame assembly is fixed between wall surfaces when a ground surface groove is formed; fixing the frame assembly between the bottom surface and the ceiling when the wall surface groove is opened; step two, controlling the distance between the two driving wheels through the distance adjusting assembly according to the width of the slot required, and controlling the two driving wheels to rotate; thirdly, the knife edges of two driving wheels in the working device are controlled by the knife rest rotating assembly to firstly contact the ground or the wall surface to start cutting, and when the cutting depth is reached, the diamond rope contacts the ground or the wall surface to start grooving; step four, controlling the diamond rope to move along the grooving direction through a moving assembly arranged on the frame assembly, and repeatedly operating until the bottom of the groove is machined; controlling the two driving wheels to return to the initial positions through the moving assembly and the tool rest rotating assembly; the building construction method is simple to operate and can quickly realize grooving.

Description

Building construction method

Technical Field

The invention belongs to the field of building construction, and particularly relates to a building construction method.

Background

In the house fitment process, in order to protect the water and electricity spool, prevent to damage the water and electricity spool and cause the potential safety hazard or cause the influence to follow-up fitment, need carry out the water and electricity fluting during most fitment. The traditional hydroelectric slotting method is to slot by holding a toothless saw and an electric hammer, and the slotting method is difficult to ensure slotting precision because of manually keeping the direction and has the hidden danger that a tool smashes a worker. Meanwhile, dust generated during construction is more, and constructors can contact the dust in a short distance, so that great harm can be generated to the health of the constructors for a long time. The existing automatic slotting machine is heavy and inconvenient to carry, is difficult to complete ground slot processing, and cannot realize automatic processing. And no matter manual grooving or automatic grooving equipment is processed, all the groove depths are processed at one time, the stress of the wall body is larger, larger noise is generated, and the potential safety hazard of the wall is easy to occur.

Disclosure of Invention

The invention aims to provide a building construction method which is simple to operate and can quickly realize grooving.

In order to solve the technical problem, the invention provides a building construction method, which comprises the following steps:

step one, fixing a frame assembly between wall surfaces when a ground surface groove is formed; fixing the frame assembly between the bottom surface and the ceiling when the wall surface groove is opened;

step two, controlling the distance between the two driving wheels through the distance adjusting assembly according to the width of the slot required, and controlling the two driving wheels to rotate;

thirdly, the knife edges of two driving wheels in the working device are controlled by the knife rest rotating assembly to firstly contact the ground or the wall surface to start cutting, and when the cutting depth is reached, the diamond rope contacts the ground or the wall surface to start grooving;

step four, controlling the diamond rope to move along the slotting direction through a moving assembly arranged on the frame assembly; after one layer of cutting is finished, the tool rest is controlled to rotate by the tool rest rotating assembly to enable the diamond rope to be close to the unprocessed wall surface, the diamond rope is controlled by the moving assembly arranged on the frame assembly to finish the next layer of cutting along the grooving direction, and the operation is repeated until the bottom of the groove is finished;

and step five, controlling the two driving wheels to return to the initial positions through the moving assembly and the tool rest rotating assembly.

Furthermore, the frame assembly comprises a first frame rod and a second frame rod which are arranged side by side, a third frame rod is fixedly arranged between one ends of the first frame rod and the second frame rod, a fourth frame rod is fixedly arranged between the other ends of the first frame rod and the second frame rod, and the first frame rod, the second frame rod, the third frame rod and the fourth frame rod are spliced to form a square; two first electric push rods are arranged on the side face of the third frame rod in parallel to the first frame rod, and a first pressing plate is arranged at one end of each first electric push rod; and two second electric push rods are arranged on the side face of the fourth frame rod in parallel to the first frame rod, and a second pressing plate is arranged at one end of each second electric push rod.

Furthermore, the moving assembly comprises a first slide bar arranged along the length direction of the first frame bar, a second slide bar arranged along the length direction of the second frame bar, a third slide bar arranged along the length direction of the third frame bar, and a fourth slide bar arranged along the length direction of the fourth frame bar; a first moving plate is connected between the first sliding rod and the second sliding rod in a sliding manner, a second moving plate is connected between the third sliding rod and the fourth sliding rod in a sliding manner, a first sliding groove is formed in the first moving plate along the length direction of the first moving plate, and a second sliding groove is formed in the second moving plate along the length direction of the second moving plate; a square sliding block is connected at the intersection of the first sliding chute and the second sliding chute in a sliding manner; a first screw rod parallel to the first sliding rod is rotatably connected to the first frame rod, the first screw rod is in threaded connection with the first moving plate, and a first moving motor for driving the first screw rod to rotate is fixedly mounted at one end of the first frame rod; and a second screw rod parallel to the fourth sliding rod is rotatably connected to the fourth frame rod, the second screw rod is in threaded connection with the second moving plate, and a second moving motor for driving the second screw rod to rotate is fixedly mounted at one end of the fourth frame rod.

Further, the tool rest rotating assembly comprises a first motor, the first motor is fixedly installed at one end of the square sliding block, an output shaft of the first motor penetrates out of the square sliding block along the direction perpendicular to the first sliding groove and the second sliding groove, a first rotating plate is fixedly installed on the output shaft of the first motor, a first supporting rod is arranged on the first rotating plate in an extending mode along the direction of the output shaft of the first motor, a second motor is fixedly installed on the first supporting rod, and a first installing plate is fixedly installed on the output shaft of the second motor.

Furthermore, a first groove rail is fixedly arranged on one side of the first mounting plate, a second groove rail is fixedly arranged on the other side of the first mounting plate, and the first groove rail and the second groove rail are positioned in the same straight line; a third groove rail is fixedly arranged on the first fixing plate along the direction vertical to the first groove rail; a first sliding block is connected in the first groove rail in a sliding manner, a second sliding block is connected in the second groove rail in a sliding manner, and a third sliding block is connected in the third groove rail in a sliding manner; a first connecting rod is hinged between the first sliding block and the third sliding block, and a second connecting rod is hinged between the second sliding block and the third sliding block; a fourth sliding block is connected in the third groove rail in a sliding mode, a second mounting plate is fixedly arranged at one end of the third groove rail on the first mounting plate, a sliding guide rod which is connected in the fourth sliding block in a sliding mode is arranged on the second mounting plate along the length direction of the third groove rail, a compressed first spring is sleeved on the sliding guide rod, and the first spring is located between the second mounting plate and the fourth sliding block and used for forcing the fourth sliding block to move towards the direction far away from the second mounting plate;

a driven wheel is rotatably connected to the fourth sliding block; the first sliding block is fixedly provided with a first support rod arranged along the direction of the third groove rail, and the second sliding block is fixedly provided with a second support rod arranged along the direction of the third groove rail; the first support rod is fixedly provided with a first grooving motor in the direction far away from the first sliding block, and the second support rod is fixedly provided with a second grooving motor in the direction far away from the second sliding block; the output shafts of the first grooving motor and the second grooving motor are fixedly provided with driving wheels, and the diamond rope is arranged between the two driving wheels and the driven wheel;

a third mounting plate is arranged on one side of the third groove rail of the first mounting plate, and a third electric push rod for driving the first sliding block to slide is fixedly mounted on the third mounting plate; when the third electric push rod extends out, the first support rod and the second support rod move back to back, and when the third electric push rod contracts, the first support rod and the second support rod move oppositely.

Advantageous effects

Compared with the prior art, the technical scheme of the invention has the following advantages:

1. according to the invention, the automatic grooving of the ground and the wall surface is realized, so that the manpower is replaced, the body health of constructors is protected, the manpower cost is saved, and the efficiency is improved.

2. The displacement of the square sliding block can be accurately controlled through the matching of the first screw rod and the first moving plate as well as the matching of the second screw rod and the second moving plate, so that the slotting of straight lines and oblique line paths can be realized, and the slotting machining quality is ensured;

3. the first rotating plate is controlled to rotate at any angle by the first motor, so that the chute processing is realized;

4. the actual working length of the diamond rope can be changed by the extension and contraction of the third electric push rod, so that the groove width can be automatically controlled;

5. the second motor controls the first mounting plate to rotate for a certain angle, so that the driving wheel feeds and processes, the groove depth is automatically controlled,

6. the diamond rope is used as a cutting tool, so that the cutting capacity is strong, the cut section is flat, and the noise is low.

7. By controlling the rapid reciprocating motion of the diamond rope and finishing the processing of fixed feeding amount, the layer cutting processing of the groove is realized, the stress of the wall is reduced, the generation of noise and potential safety hazard of the wall is avoided, and the quality of the groove is also improved;

8. the first electric push rod and the second electric push rod are fixed in an extending mode, so that the floor slotting can be completed by horizontally placing the electric push rods, and the wall slotting can also be completed by vertically placing the electric push rods.

Drawings

FIG. 1 is a front view of a processing apparatus of the present invention in a vertical state;

FIG. 2 is a three-dimensional structural view of a processing apparatus according to the present invention;

FIG. 3 is a three-dimensional structural view of a working device according to the present invention;

FIG. 4 is a left side view of the working device of the present invention;

FIG. 5 is a left side view of the working device of the present invention in a first cutting mode;

FIG. 6 is a left side view of the working device of the present invention in a second reciprocation state;

FIG. 7 is a front view of the working device of the present invention;

FIG. 8 is a front view of the working device of the present invention after the width of the slot is changed;

fig. 9 is a three-dimensional structure view of a driving wheel driving the diamond rope in fig. 3 according to the present invention.

Detailed Description

Referring to fig. 1 to 9, the present invention provides a building construction method, including the steps of:

step two, according to the width of the required slot, the distance between the two driving wheels 215 is controlled by the distance adjusting component, and the two driving wheels 215 are controlled to rotate;

step three, controlling the cutting edges 215a of two driving wheels 215 in the working device to firstly contact the ground or the wall surface to start cutting through the tool rest rotating assembly, and starting to cut the groove when the diamond rope 217 contacts the ground or the wall surface after the cutting depth is reached;

step four, controlling the diamond rope 217 to move along the slotting direction through a moving assembly arranged on the frame assembly; after one layer of cutting is finished, the tool rest is controlled to rotate by the tool rest rotating assembly to enable the diamond rope 217 to be close to the unprocessed wall surface, the diamond rope 217 is controlled to finish the next layer of cutting along the grooving direction by the moving assembly arranged on the frame assembly continuously, and the operation is repeated until the bottom of the groove is finished;

and step five, controlling the two driving wheels 215 to return to the initial position through the moving assembly and the tool rest rotating assembly.

The frame component comprises a first frame rod 107 and a second frame rod 114 which are arranged side by side, a third frame rod 112 is fixedly arranged between one ends of the first frame rod 107 and the second frame rod 114, a fourth frame rod 102 is fixedly arranged between the other ends of the first frame rod 107 and the second frame rod 114, and the first frame rod 107, the second frame rod 114, the third frame rod 112 and the fourth frame rod 102 are spliced to form a square; two first electric push rods 101 are arranged on the side face of the third frame rod 112 in parallel to the first frame rod 107, and a first pressing plate 101a is arranged at one end of each first electric push rod 101; two second electric push rods 199 are arranged on the side face of the fourth frame rod 102 in parallel to the first frame rod 107, and a second pressing plate 199a is arranged at one end of each second electric push rod 199.

The moving assembly includes a first slide bar 108 disposed along a length direction of the first frame bar 107, a second slide bar 115 disposed along a length direction of the second frame bar 114, a third slide bar 113 disposed along a length direction of the third frame bar 112, and a fourth slide bar 103 disposed along a length direction of the fourth frame bar 102; a first moving plate 110 is connected between the first slide bar 108 and the second slide bar 115 in a sliding manner, a second moving plate 105 is connected between the third slide bar 113 and the fourth slide bar 103 in a sliding manner, a first sliding groove 110a is formed in the first moving plate 110 along the length direction of the first moving plate, and a second sliding groove 105a is formed in the second moving plate 105 along the length direction of the second moving plate; a square sliding block 202 is connected to the intersection of the first sliding groove 110a and the second sliding groove 105a in a sliding manner; a first screw 109 parallel to the first slide bar 108 is rotatably connected to the first frame bar 107, the first screw 109 is in threaded connection with a first moving plate 110, and a first moving motor 111 for driving the first screw 109 to rotate is fixedly mounted at one end of the first frame bar 107; a second screw 104 parallel to the fourth sliding rod 103 is rotatably connected to the fourth frame rod 102, the second screw 104 is in threaded connection with a second moving plate 105, and a second moving motor 106 for driving the second screw 104 to rotate is fixedly mounted at one end of the fourth frame rod 102.

The tool rest rotating assembly comprises a first motor 201, the first motor 201 is fixedly installed at one end of a square sliding block 202, an output shaft of the first motor 201 penetrates out along a direction perpendicular to a first sliding groove 110a and a second sliding groove 105a and is fixedly installed with a first rotating plate 203, a first supporting rod 203a is arranged on the first rotating plate 203 in an extending mode along the direction of the output shaft of the first motor 201, a second motor 218 is fixedly installed on the first supporting rod 203a, and a first installing plate 204 is fixedly installed on the output shaft of the second motor 218.

A first groove rail 209a is fixedly installed on one side of the first installation plate 204, a second groove rail 209b is fixed on the other side of the first installation plate, and the first groove rail 209a and the second groove rail 209b are located in the same straight line; a third groove rail 205 is fixedly arranged on the first fixing plate along the direction vertical to the first groove rail 209 a; a first sliding block 220a is connected in the first slot track 209a in a sliding manner, a second sliding block 220b is connected in the second slot track 209b in a sliding manner, and a third sliding block 206 is connected in the third slot track 205 in a sliding manner; a first connecting rod 207 is hinged between the first sliding block 220a and the third sliding block 206, and a second connecting rod 208 is hinged between the second sliding block 220b and the third sliding block 206; third slotted track 205 sliding connection has fourth slider 211, first mounting panel 204 is equipped with second mounting panel 213a in the one end of third slotted track 205 is fixed, be equipped with sliding connection in fourth slider 211's the slide bar 213b that leads along the length direction of third slotted track 205 on the second mounting panel 213a, lead and cup joint the first spring 213 that is compressed on the slide bar 213b, first spring 213 is located and is used for forcing fourth slider 211 to keeping away from second mounting panel 213a direction motion between second mounting panel 213a and the fourth slider 211.

A driven wheel 212 is rotatably connected to the fourth sliding block 211; a first support rod 210a arranged along the direction of the third groove track 205 is fixedly installed on the first sliding block 220a, and a second support rod 210b arranged along the direction of the third groove track 205 is fixedly installed on the second sliding block 220 b; the first support bar 210a is fixedly provided with a first slotting motor 214a in the direction away from the first sliding block 220a, and the second support bar 210b is fixedly provided with a second slotting motor 214b in the direction away from the second sliding block 220 b; the output shafts of the first grooving motor 214a and the second grooving motor 214b are fixedly provided with driving wheels 215, and the diamond rope 217 is arranged between the two driving wheels 215 and the driven wheel 212; a third mounting plate 213c is arranged on one side of the third groove rail 205 of the first mounting plate 204, and a third electric push rod 219 for driving the first slider 220a to slide is fixedly mounted on the third mounting plate 213 c; when the third electric putter 219 is extended, the first and

second struts

210a and 210b are moved away from each other, and when the third electric putter 219 is contracted, the first and

second struts

210a and 210b are moved toward each other.

In the first step, when the frame assembly works, the first electric push rod 101 and the second electric push rod 199 are controlled to extend out, so that the frame assembly is fixed. In addition, after the fixing of the frame assembly is completed, it should be confirmed that the first spring 213 is in a compressed state, and since the first spring 213 is located between the second mounting plate 213a and the fourth slider 211, the fourth slider 211 can slide on the third groove rail 205, and the diamond wire 217 is wound around the two

driving pulleys

215 and 212 and is kept tight.

In the second step, when the slot width is controlled (see fig. 3, 7, and 8 for details), the first slider 220a can move in the first slot track 209a, the second slider 220b can move in the second slot track 209b, and the third slider 206 can move in the third slot track 205; when the third electric push rod 219 extends, the first slider 220a drives the first cutting motor to move in a direction away from the third slot track 205 through the first support rod 210a, and the second slider 220b drives the second cutting motor to move in a direction away from the third slot track 205 through the second support rod 210 b; at this time, the two driving wheels 215 move back to back, and the driven wheel 212 moves towards the direction close to the second mounting plate 213a under the tension action of the diamond rope 217, so that the distance between the driving wheels 215 is increased, the groove width is automatically increased, and similarly, the groove width is automatically reduced only by the third electric push rod 219. After the grooving width changing operation is completed, the first grooving motor 214a and the second grooving motor 214b are activated to rotate the two driving wheels 215 and simultaneously drive the diamond wire 217 wound around the driving wheels 215 and the driven wheels 212 to start rapid displacement.

In the third step, when the blades 215a of the two driving wheels 215 in the working device first contact the ground or the wall to start cutting, the first motor 201 is first controlled to start, so that the first rotating plate 203 drives the third groove rail 205 to face the grooving direction, and the second motor 218 is controlled to start, so that the first mounting plate 204 rotates to the initial working position (see fig. 5), and further the blades 215a (see fig. 9) on the driving wheels 215 are first contacted with the wall to start cutting.

After one layer of cutting is finished, the second motor 218 rotates to a certain angle (see fig. 4, 5 and 6), so that the diamond rope 217 is close to the unprocessed wall surface, then the power assembly controls the diamond rope 217 to finish the next layer of cutting along the slotting path, and after each rotation of the second motor 218, the power assembly controls the diamond rope 217 to finish one cutting, and the action is repeated until the bottom of the slot is processed.

In this embodiment, since the square sliding block 202 can slide in the first sliding slot 110a and the second sliding slot 105a (see fig. 2), when the two driving wheels 215 need to move horizontally, the second moving motor 106 is started to drive the second screw 104 on the fourth frame rod 102 to rotate, and since the second moving plate 105 is engaged with the second screw 104, the second moving rod can move along the third sliding rod 113 and the fourth sliding rod 103, and at this time, the two driving wheels 215 feed horizontally. When the two driving wheels 215 need to move vertically, the first moving motor 111 is activated to drive the first screw 109 on the first frame bar 107 to rotate, and because the first moving plate 110 is engaged with the first screw 109, the first moving bar can move along the first sliding bar 108 and the second sliding bar 115, and at this time, the two driving wheels 215 vertically feed. When the chute needs to be opened, the first moving motor 111 and the second moving motor 106 are started simultaneously, so that the two driving wheels 215 are fed in the horizontal direction and the vertical direction simultaneously, and the inclination angles of the working paths of the two driving wheels 215 can be controlled by controlling the displacement speeds in the horizontal direction and the vertical direction.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the technical principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. A building construction method is characterized by comprising the following steps:

2. The building construction method according to claim 1, characterized in that: the frame assembly comprises a first frame rod and a second frame rod which are arranged side by side, a third frame rod is fixedly arranged between one ends of the first frame rod and the second frame rod, a fourth frame rod is fixedly arranged between the other ends of the first frame rod and the second frame rod, and the first frame rod, the second frame rod, the third frame rod and the fourth frame rod are spliced to form a square; two first electric push rods are arranged on the side face of the third frame rod in parallel to the first frame rod, and a first pressing plate is arranged at one end of each first electric push rod; and two second electric push rods are arranged on the side face of the fourth frame rod in parallel to the first frame rod, and a second pressing plate is arranged at one end of each second electric push rod.

3. The building construction method according to claim 2, characterized in that: the moving assembly comprises a first slide bar arranged along the length direction of the first frame bar, a second slide bar arranged along the length direction of the second frame bar, a third slide bar arranged along the length direction of the third frame bar, and a fourth slide bar arranged along the length direction of the fourth frame bar; a first moving plate is connected between the first sliding rod and the second sliding rod in a sliding manner, a second moving plate is connected between the third sliding rod and the fourth sliding rod in a sliding manner, a first sliding groove is formed in the first moving plate along the length direction of the first moving plate, and a second sliding groove is formed in the second moving plate along the length direction of the second moving plate; a square sliding block is connected at the intersection of the first sliding chute and the second sliding chute in a sliding manner; a first screw rod parallel to the first sliding rod is rotatably connected to the first frame rod, the first screw rod is in threaded connection with the first moving plate, and a first moving motor for driving the first screw rod to rotate is fixedly mounted at one end of the first frame rod; and a second screw rod parallel to the fourth sliding rod is rotatably connected to the fourth frame rod, the second screw rod is in threaded connection with the second moving plate, and a second moving motor for driving the second screw rod to rotate is fixedly mounted at one end of the fourth frame rod.

4. The building construction method according to claim 3, characterized in that: the tool rest rotating assembly comprises a first motor, the first motor is fixedly installed at one end of the square sliding block, an output shaft of the first motor penetrates out of the square sliding block along the direction perpendicular to the first sliding groove and the second sliding groove, a first rotating plate is fixedly installed on the output shaft of the first motor, a first supporting rod is arranged on the first rotating plate in an extending mode along the direction of the output shaft of the first motor, a second motor is fixedly installed on the first supporting rod, and a first installing plate is fixedly installed on the output shaft of the second motor.

5. The building construction method according to claim 4, characterized in that: a first groove rail is fixedly arranged on one side of the first mounting plate, a second groove rail is fixedly arranged on the other side of the first mounting plate, and the first groove rail and the second groove rail are positioned in the same straight line; a third groove rail is fixedly arranged on the first fixing plate along the direction vertical to the first groove rail; a first sliding block is connected in the first groove rail in a sliding manner, a second sliding block is connected in the second groove rail in a sliding manner, and a third sliding block is connected in the third groove rail in a sliding manner; a first connecting rod is hinged between the first sliding block and the third sliding block, and a second connecting rod is hinged between the second sliding block and the third sliding block; a fourth sliding block is connected in the third groove rail in a sliding mode, a second mounting plate is fixedly arranged at one end of the third groove rail on the first mounting plate, a sliding guide rod which is connected in the fourth sliding block in a sliding mode is arranged on the second mounting plate along the length direction of the third groove rail, a compressed first spring is sleeved on the sliding guide rod, and the first spring is located between the second mounting plate and the fourth sliding block and used for forcing the fourth sliding block to move towards the direction far away from the second mounting plate;