CN215150676U - Environment-friendly inorganic stone infrared bridge cutting machine - Google Patents

Abstract

The utility model discloses an environment-friendly inorganic stone infrared bridge cutting machine, which comprises a base, a three-dimensional cutting chamber and a control and liquid supply mechanism; the three-dimensional cutting chamber comprises a transverse and longitudinal mechanism, a cutting mechanism, a lifting mechanism and a storage plate; the utility model controls the cutting mechanism to move in the transverse and longitudinal directions through the transverse and longitudinal mechanisms, and then controls the lifting of the transverse and longitudinal mechanisms through the telescopic hydraulic cylinder and three vertical limiting slide bars in the lifting mechanism; when the lifting is required, the telescopic hydraulic cylinder extends to drive the transverse and longitudinal mechanism to lift, and the three vertical limiting sliding rods are matched with the first limiting block, the second limiting block and the fourth limiting block in the transverse and longitudinal mechanism in a coordinated manner, so that the transverse and longitudinal mechanism can lift stably; when the descending is to be realized, the telescopic hydraulic cylinder is contracted to drive the transverse and longitudinal mechanism to descend, the three vertical limiting sliding rods limit the first limiting blocks, the second limiting blocks and the fourth limiting blocks in the transverse and longitudinal mechanism to be matched in a synergic mode, so that the transverse and longitudinal mechanism descends stably, and finally the cutting knife can cut environment-friendly inorganic stones stably and accurately.

Description

Environment-friendly inorganic stone infrared bridge cutting machine

Technical Field

The utility model relates to an inorganic stone cutting technical field, concretely relates to inorganic stone infrared bridge cutting machine of environmental protection.

Background

The infrared cutting machine is mainly used for cutting stone materials by infrared rays, and is a standard specification board required by fast, accurate and continuous cutting of cut and polished rough boards, plastics, glass, cement boards and the like according to requirements, and belongs to high-precision cutting machinery.

However, in the prior art, the infrared bridge cutting machine uses a separate cylinder to control the lifting of the cutting knife, so that the cutting knife is inevitably shaken in the lifting process, which causes influence on the cutting precision,

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing one kind can be make cutting mechanism and horizontal vertical mechanism steady lift's environmental protection inorganic stone infrared bridge cutting machine.

In order to solve the technical problem, the technical scheme of the utility model is that: an environment-friendly inorganic stone infrared bridge cutting machine comprises a base, a three-dimensional cutting chamber arranged above the base, a controller arranged on one side of the three-dimensional cutting chamber, and a liquid supply mechanism arranged on the other side of the three-dimensional cutting chamber; the three-dimensional cutting room comprises a transverse and longitudinal mechanism, a cutting mechanism arranged between the transverse and longitudinal mechanisms, a lifting mechanism arranged below the transverse and longitudinal mechanism and arranged at four corners of the transverse and longitudinal mechanism, and a storage plate arranged below the cutting mechanism.

Preferably, the transverse and longitudinal mechanism comprises a transverse moving assembly, longitudinal moving assemblies arranged on two sides of the transverse moving assembly, and a supporting frame arranged on the periphery of the transverse moving assembly and the longitudinal moving assembly.

Preferably, the lateral movement assembly includes a first moving block, a second moving block disposed at one side of the first moving block, a lateral lead screw disposed between the first moving block and the second moving block, a lateral slide bar disposed at one side of the lateral lead screw, and a lateral motor disposed at one side of the lateral lead screw.

Preferably, the longitudinal moving assembly comprises a longitudinal screw rod, a longitudinal sliding rod arranged on one side of the longitudinal screw rod, and a longitudinal motor arranged at one end of the longitudinal screw rod.

Preferably, the support frame comprises a first fixed rod, a second fixed rod, a third fixed rod and a fourth fixed rod, a first limiting block arranged at the joint of the first fixed rod and the second fixed rod, a second limiting block arranged at the joint of the second fixed rod and the third fixed rod, a third limiting block arranged at the joint of the third fixed rod and the fourth fixed rod, and a fourth limiting block arranged at the joint of the fourth fixed rod and the first fixed rod.

Preferably, the lifting mechanism comprises a telescopic hydraulic cylinder and three vertical limiting slide rods which are arranged on one side of the telescopic hydraulic cylinder and used for supporting the transverse and longitudinal mechanisms to move up and down.

Preferably, the liquid supply mechanism comprises a liquid storage tank and a water suction pump arranged above the liquid storage tank.

Preferably, the cutting mechanism comprises a mobile control box, a rotating motor arranged below the mobile control box, a cutting knife arranged at the output end of the rotating motor, an infrared aligner arranged below the rotating motor, and an injection head arranged on one side of the cutting knife.

Preferably, a connecting pipe is arranged between the liquid supply mechanism and the cutting mechanism.

The utility model discloses technical effect mainly embodies: the utility model controls the cutting mechanism to move in the transverse and longitudinal directions through the transverse and longitudinal mechanisms, and then controls the lifting of the transverse and longitudinal mechanisms through the telescopic hydraulic cylinder and three vertical limiting slide bars in the lifting mechanism; when the lifting is required, the telescopic hydraulic cylinder extends to drive the transverse and longitudinal mechanism to lift, and the three vertical limiting sliding rods are matched with the first limiting block, the second limiting block and the fourth limiting block in the transverse and longitudinal mechanism in a coordinated manner, so that the transverse and longitudinal mechanism can lift stably; when the descending is to be realized, the telescopic hydraulic cylinder is contracted to drive the transverse and longitudinal mechanism to descend, the three vertical limiting sliding rods limit the first limiting blocks, the second limiting blocks and the fourth limiting blocks in the transverse and longitudinal mechanism to be matched in a synergic mode, so that the transverse and longitudinal mechanism descends stably, and finally the cutting knife can cut environment-friendly inorganic stones stably and accurately.

Drawings

FIG. 1 is a schematic view of an environment-friendly inorganic stone infrared bridge cutting machine of the present invention;

FIG. 2 is a top view of FIG. 1;

fig. 3 is a schematic structural view of the horizontal and vertical mechanism and the cutting mechanism in fig. 1 after descending.

Detailed Description

The following detailed description of the embodiments of the present invention is made with reference to the accompanying drawings, so that the technical solution of the present invention can be more easily understood and grasped.

In the present embodiment, it should be understood that the terms "middle", "upper", "lower", "top", "right", "left", "above", "back", "middle", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the present invention, and do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the present embodiment, if the connection or fixing manner between the components is not specifically described, the connection or fixing manner may be a bolt fixing manner, a pin connecting manner, or the like, which is commonly used in the prior art, and therefore, details thereof are not described in the present embodiment.

An environment-friendly inorganic stone infrared bridge cutting machine is shown in figures 1-3 and comprises a base 1, a three-dimensional cutting chamber 2 arranged above the base 1, a controller 3 arranged on one side of the three-dimensional cutting chamber 2, and a liquid supply mechanism 4 arranged on the other side of the three-dimensional cutting chamber 2; the stereo cutting room 2 comprises transverse and longitudinal mechanisms 21, cutting mechanisms 22 arranged between the transverse and longitudinal mechanisms 21, lifting mechanisms 23 arranged below the transverse and longitudinal mechanisms 21 and arranged at four corners of the transverse and longitudinal mechanisms 21, and object placing plates 24 arranged below the cutting mechanisms 22.

The transverse and longitudinal mechanism 21 comprises a transverse moving component 211, longitudinal moving components 212 arranged at two sides of the transverse moving component 211, and a supporting frame 213 arranged at the periphery of the transverse moving component 211 and the longitudinal moving components 212.

The transverse moving assembly 211 includes a first moving block 2111, a second moving block 2112 disposed on one side of the first moving block 2111, a transverse lead screw 2113 disposed between the first moving block 2111 and the second moving block 2112, a transverse slide bar 2114 disposed on one side of the transverse lead screw 2113, and a transverse motor 2115 disposed on one side of the transverse lead screw 2113. The cutting mechanism 22 is arranged on a transverse screw 2113 and a transverse sliding bar 2114 and is driven to run by the forward and reverse rotation of a transverse motor 2115. The first moving block 2111 is installed above the longitudinal lead screw 2121 and the first fixing rod 2131, and the second moving block 2112 is installed above the longitudinal sliding bar 2122 and the third fixing rod 2133.

The longitudinal moving assembly 212 includes a longitudinal screw 2121, a longitudinal slide rod 2122 disposed at one side of the longitudinal screw 2121, and a longitudinal motor 2123 disposed at one end of the longitudinal screw 2121. The transverse moving component 211 is moved by a longitudinal motor 2123.

The supporting frame 213 comprises a first fixing rod 2131, a second fixing rod 2132, a third fixing rod 2133 and a fourth fixing rod 2134, a first limiting block 2135 arranged at the joint of the first fixing rod 2131 and the second fixing rod 2132, a second limiting block 2136 arranged at the joint of the second fixing rod 2132 and the third fixing rod 2133, a third limiting block 2137 arranged at the joint of the third fixing rod 2133 and the fourth fixing rod 2134, and a fourth limiting block 2138 arranged at the joint of the fourth fixing rod 2134 and the first fixing rod 2131. Wherein the first 2135, the second 2136 and the fourth 2138 limiting blocks can slide on the vertical limiting slide bar 232. The third limiting block 2137 is fixedly installed at the output end of the telescopic hydraulic cylinder 231.

The lifting mechanism 23 comprises a telescopic hydraulic cylinder 231 and three vertical limiting slide rods 232 which are arranged on one side of the telescopic hydraulic cylinder 231 and used for supporting the transverse and longitudinal mechanism 21 to move up and down. The telescopic hydraulic cylinder 231 drives the transverse and longitudinal mechanism 21 to move up and down when telescopic, and the vertical limiting slide rod 232 can enable the transverse and longitudinal mechanism 21 to keep horizontal lifting.

The liquid supply mechanism 4 comprises a liquid storage tank 41 and a water suction pump 42 arranged above the liquid storage tank 41. The suction pump 42 delivers the cutting fluid of the reservoir 41 to the spray head 225 through the connection pipe 101.

The cutting mechanism 22 comprises a mobile control box 221, a rotating motor 222 arranged below the mobile control box 221, a cutting knife 223 arranged at the output end of the rotating motor 222, an infrared aligner 224 arranged below the rotating motor 222, and an injection head 225 arranged at one side of the cutting knife 223. The environmental inorganic stone to be cut is aligned by the infrared aligner 224, and the cutting knife 223 is driven by the rotating motor 222 to rotate, so that the cutting knife 223 cuts the inorganic stone.

A connecting pipe 101 is arranged between the liquid supply mechanism 4 and the cutting mechanism 22.

The controller 3 in this embodiment is a PLC controller of a type S7-200; the transverse motor 2115 is a servo motor with the model number of 1FL6022-2AF21-1AA 1; the model of the longitudinal motor 2123 is a servo motor of 1FL6022-2AF21-1AA 1; the model of the rotating motor 222 is YX3-100L 2-4; the telescopic hydraulic cylinder 231 is of the type HOB80 × 40 × 350; the type of the water suction pump 42 is ZX 100-100-20.

The utility model discloses technical effect mainly embodies: the utility model controls the cutting mechanism to move in the transverse and longitudinal directions through the transverse and longitudinal mechanisms, and then controls the lifting of the transverse and longitudinal mechanisms through the telescopic hydraulic cylinder and three vertical limiting slide bars in the lifting mechanism; when the lifting is required, the telescopic hydraulic cylinder extends to drive the transverse and longitudinal mechanism to lift, and the three vertical limiting sliding rods are matched with the first limiting block, the second limiting block and the fourth limiting block in the transverse and longitudinal mechanism in a coordinated manner, so that the transverse and longitudinal mechanism can lift stably; when the descending is to be realized, the telescopic hydraulic cylinder is contracted to drive the transverse and longitudinal mechanism to descend, the three vertical limiting sliding rods limit the first limiting blocks, the second limiting blocks and the fourth limiting blocks in the transverse and longitudinal mechanism to be matched in a synergic mode, so that the transverse and longitudinal mechanism descends stably, and finally the cutting knife can cut environment-friendly inorganic stones stably and accurately.

Of course, the above is only a typical example of the present invention, and besides, the present invention can also have other various specific embodiments, and all technical solutions adopting equivalent replacement or equivalent transformation are all within the scope of the present invention as claimed.

Claims (9)

1. An environment-friendly inorganic stone infrared bridge cutting machine comprises a base, a three-dimensional cutting chamber arranged above the base, a controller arranged on one side of the three-dimensional cutting chamber, and a liquid supply mechanism arranged on the other side of the three-dimensional cutting chamber; the method is characterized in that: the three-dimensional cutting room comprises a transverse and longitudinal mechanism, a cutting mechanism arranged between the transverse and longitudinal mechanisms, a lifting mechanism arranged below the transverse and longitudinal mechanism and arranged at four corners of the transverse and longitudinal mechanism, and a storage plate arranged below the cutting mechanism.

2. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 1, wherein: the transverse and longitudinal mechanism comprises a transverse moving assembly, longitudinal moving assemblies arranged on two sides of the transverse moving assembly and a supporting frame arranged on the periphery of the transverse moving assembly and the longitudinal moving assemblies.

3. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 2, wherein: the transverse moving assembly comprises a first moving block, a second moving block arranged on one side of the first moving block, a transverse lead screw arranged between the first moving block and the second moving block, a transverse sliding rod arranged on one side of the transverse lead screw, and a transverse motor arranged on one side of the transverse lead screw.

4. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 2, wherein: the longitudinal moving assembly comprises a longitudinal screw rod, a longitudinal sliding rod arranged on one side of the longitudinal screw rod and a longitudinal motor arranged at one end of the longitudinal screw rod.

5. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 2, wherein: the support frame comprises a first fixed rod, a second fixed rod, a third fixed rod, a fourth fixed rod, a first limiting block arranged at the joint of the first fixed rod and the second fixed rod, a second limiting block arranged at the joint of the second fixed rod and the third fixed rod, a third limiting block arranged at the joint of the third fixed rod and the fourth fixed rod, and a fourth limiting block arranged at the joint of the fourth fixed rod and the first fixed rod.

6. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 1, wherein: the lifting mechanism comprises a telescopic hydraulic cylinder and three vertical limiting slide rods which are arranged on one side of the telescopic hydraulic cylinder and are used for supporting the transverse and longitudinal mechanism to move up and down.

7. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 1, wherein: the liquid supply mechanism comprises a liquid storage tank and a water suction pump arranged above the liquid storage tank.

8. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 1, wherein: the cutting mechanism comprises a mobile control box, a rotating motor arranged below the mobile control box, a cutting knife arranged at the output end of the rotating motor, an infrared aligner arranged below the rotating motor and an injection head arranged on one side of the cutting knife.

9. The environment-friendly inorganic stone infrared bridge cutting machine as claimed in claim 1, wherein: and a connecting pipe is arranged between the liquid supply mechanism and the cutting mechanism.

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