CN115946163A - Cutting device is used in processing of rock wool board - Google Patents

Abstract

The invention discloses a cutting device for rock wool board processing, relates to the technical field of rock wool board processing, and has the advantage of fixing rock wool boards during cutting of the rock wool boards, and the key points of the technical scheme are as follows: the rock wool plate cutting machine comprises a transmission roller assembly for transmitting rock wool plates, a belt pressing assembly arranged on one side of the transmission roller assembly, and a cutting assembly arranged on one side of the belt pressing assembly; the connecting plates are respectively provided with a straightening piece for straightening the rock wool plates above the conveying rollers, and the first support is provided with a driving piece for driving each conveying roller to rotate; the belt compresses tightly the subassembly including setting up the second support of two relative distributions in the transmission roller export, and the both ends of two second supports are all rotated and are equipped with the axis of rotation, and two axes of rotation are passed through the first transmission belt of annular and are connected, one of them be equipped with drive axis of rotation pivoted first motor on the second support, two second support upper ends all are equipped with the riser, are equipped with between two risers and compress tightly the rock wool board piece that compresses tightly on first transmission belt.

Description

Cutting device is used in processing of rock wool board

Technical Field

The invention relates to the technical field of rock wool board processing, in particular to a cutting device for rock wool board processing.

Background

The artificial inorganic fiber is processed by melting the rock wool board at high temperature, and has the characteristics of light weight, small heat conductivity coefficient, heat absorption and non-combustion.

Chinese patent with publication number CN209521119U discloses a cutting equipment is used in rock wool board processing, including support, conveyer belt and compression roller, support upper end left side is equipped with the conveyer belt, support upper end middle part is equipped with the compression roller, the compression roller right side is equipped with the cutting roller, the cutting roller right side is equipped with the shield, the shield is equipped with the pivot with leg joint play, the pivot is through pivot support fixed connection support, the cutting roller rotates to be connected and cuts the cutting roller support, and cuts cutting roller support fixed connection support, reduces the resistance in the data send process, and when the rock wool board moved to the compression roller lower extreme, compression roller laminating rock wool board upper surface is fixed and is conveyed the compression roller, and during the cutting, it rocks to reduce the rock wool board to improve rock wool board processingquality, when having solved current rock wool board cutting, the fixed rock wool board, the shake of rock wool board influences the technical problem of cutting quality. The applicant develops another technical scheme in the actual work to solve the technical problems that when the existing rock wool board is cut, the rock wool board is unstable in fixation, and shakes to influence the cutting quality.

Disclosure of Invention

In view of the technical shortcomings, the invention aims to provide a cutting device for processing a rock wool board, which has the advantage of fixing the rock wool board during cutting of the rock wool board.

In order to solve the technical problem, the invention adopts the following technical scheme:

the invention provides a cutting device for processing a rock wool plate, which comprises a transmission roller assembly for transmitting the rock wool plate, a belt pressing assembly arranged on one side of the transmission roller assembly, and a cutting assembly arranged on one side of the belt pressing assembly;

the transmission roller assembly comprises two first supports which are oppositely arranged on the ground and a plurality of transmission rollers which are rotatably connected to the two first supports, each transmission roller is positioned on the same plane, a gap is formed between every two adjacent transmission rollers, the two first supports are provided with connecting plates below the transmission rollers, namely, two ends of each connecting plate are fixed on the two first supports, the connecting plates are provided with straightening pieces for straightening rock wool boards above the transmission rollers, and the first supports are provided with driving pieces for driving the transmission rollers to rotate;

the belt compresses tightly the subassembly including setting up two relative distribution's in the transmission roller export second support, two the both ends of second support are all rotated and are equipped with the axis of rotation, and two axes of rotation are passed through the first transmission belt of annular and are connected, one of them be equipped with drive axis of rotation pivoted first motor on the second support, two second support upper end all is equipped with the riser, two be equipped with between the riser and compress tightly the piece that compresses tightly on first transmission belt with the rock wool board.

Through adopting above-mentioned technical scheme, the rock wool board that will treat cutting process is placed on the transmission roller, each transmission roller transmits the rock wool board to first transmission belt this moment on, the piece of putting right at this in-process puts the rock wool board right, reduce the slope of rock wool board, improve the precision of rock wool board cutting, when transmitting to first transmission belt on, the setting that compresses tightly makes the rock wool board compressed tightly, when the one end of rock wool board was transmitted out first transmission belt, cutting assembly cuts the rock wool board of pair output, all the other rock wool boards compressed tightly on first transmission belt by compressing tightly this moment, reduce the shake of rock wool board, when the cutting of rock wool board, it is fixed with the rock wool board, improve the cutting quality.

Preferably, the piece of ajusting includes fixed first board, the second board of connection on the connecting plate that slides that sets up on the connecting plate, the moving direction of second board removes along the length direction of transmission roller, the upper end of first board and second board all extends the upper end of transmission roller and is equipped with the first stripper plate and the second stripper plate of perpendicular to transmission roller length direction respectively in the one end that extends, be equipped with the power spare that drives the second board and remove to first board direction on the connecting plate, first board and second board extend to the transmission roller upper end through the clearance between two adjacent transmission rollers.

Preferably, the connecting plate is including setting up two guide bars on two first supports, two the length direction of guide bar is along the length direction of transmission roller, two fixed being equipped with first dead lever between the guide bar and sliding connection have the second dead lever, power spare is including rotating first pendulum board and the second pendulum board that sets up on first dead lever and second dead lever respectively, first pendulum board and second pendulum board rotate the one end of keeping away from first dead lever and second dead lever respectively and are equipped with first gear and second gear, first gear and second gear intermeshing, first gear and second gear rotate the position of being connected with first pendulum board and second pendulum board respectively through the pivot and rotate and be connected, the one end of pivot is fixed on first pendulum board and second pendulum board, two the pivot is connected through the transition pole in the one end that extends first gear and second gear, the both ends of transition pole rotate with two pivots respectively and are connected, the first board is fixed on first dead lever, the second board is fixed on the second dead lever, the first dead lever is equipped with the second motor that drives first pendulum board and rotate.

Preferably, one end of each transmission roller extends out of one side face of the first support, and a driving wheel is coaxially arranged at the extended end of each transmission roller, the driving piece comprises an annular chain connected with each driving wheel, and a third motor for driving one transmission roller to rotate is arranged on the first support.

Preferably, the pressing piece comprises a second transmission belt arranged on the vertical plate, and when the rock wool plate is transmitted on the first transmission belt, the transmission directions of the first transmission belt and the second transmission belt are consistent.

Preferably, the pressing piece comprises a transverse plate arranged between two vertical plates, the transverse plate is distributed along the length direction of the first transmission belt, a plurality of rectangular frames are arranged on the transverse plate along the length direction of the transverse plate, a moving block is connected in each rectangular frame in a sliding manner, two moving columns are connected at one ends of the moving blocks towards the first transmission belt in a sliding manner, balls are embedded at one ends of the moving columns towards the first transmission belt, a driving piece for driving each moving block to move up and down in the moving frame is arranged at the upper end of the transverse plate, and when the driving piece drives the moving blocks to move downwards to enable the moving columns to abut against the rock wool plate, a limiting piece for limiting the positions of the moving columns is arranged on each moving block.

Preferably, the driving part comprises pushing rods arranged at the upper ends of the moving blocks, one end of each pushing rod penetrates through the transverse plate and is located above the transverse plate, one end of each pushing rod penetrating out of the upper portion of the transverse plate is connected with the corresponding pushing plate through a push plate, and a cylinder for driving the push plate to move up and down is arranged on the transverse plate.

Preferably, the limiting part comprises a moving hole which is formed in the moving block and is used for the moving column to reciprocate and a communicating hole which is communicated with the two moving holes, the communicating hole is located on one side of the moving hole, a sliding block is connected in the communicating hole in a sliding mode, first inclined planes are arranged at two ends of the sliding block, a second inclined plane which is matched with the first inclined plane is arranged at one end, close to the sliding block, of the moving column, one side face, away from the transverse plate, of the moving block extends out of one end of the moving column, first sliding grooves which are distributed in the length direction of the moving column are formed in each moving column, second sliding grooves which are distributed in the length direction of the sliding block are formed in the sliding block, and a first rod which enters the first sliding grooves and a second rod which enters the second sliding grooves are connected to the moving block through threads.

Preferably, the second support is provided with a supporting block for supporting the upper belt below the upper belt of the annular first transmission belt, a plurality of rollers are embedded at positions where the supporting block contacts with the upper belt of the first transmission belt, the length direction of each roller is distributed along the transmission direction perpendicular to the first transmission belt, and each roller is distributed along the transmission direction of the first transmission belt.

Preferably, the cutting assembly comprises two opposite third supports arranged at the outlet of the first transmission belt, a material receiving plate is arranged between the two opposite third supports, the upper end and the lower end of each third support on the material receiving plate are respectively connected with a cutting roller in a rotating mode, a plurality of cutting sawteeth are arranged on the cutting rollers, openings for extending the cutting sawteeth on the cutting rollers below the material receiving plate to the upper end face of the material receiving plate are formed in the material receiving plate, the cutting sawteeth on the cutting rollers are distributed correspondingly, and a fourth motor for driving the two cutting rollers to rotate is arranged on each third support.

The invention has the beneficial effects that: the rock wool board that will treat cutting processing is placed on the transmission roller, each transmission roller transmits the rock wool board to first transmission belt this moment, the piece of putting right at this in-process puts the rock wool board, reduce the slope of rock wool board, improve the precision of rock wool board cutting, when transmitting to first transmission belt on, the setting that compresses tightly makes the rock wool board compressed tightly, when the one end of rock wool board was transmitted out first transmission belt, cutting assembly cuts the rock wool board of pair output, all the other rock wool boards compressed tightly on first transmission belt this moment, reduce the shake of rock wool board, when the cutting of rock wool board, it is fixed with the rock wool board, improve the cutting quality.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of the present embodiment;

FIG. 2 is a schematic structural diagram of a connecting plate according to the present embodiment;

fig. 3 is a schematic structural view for embodying the second transfer belt of the present embodiment;

FIG. 4 is a schematic structural diagram of a rectangular frame according to the present embodiment;

FIG. 5 is a schematic structural diagram of the present embodiment for embodying the supporting block;

fig. 6 is a schematic structural diagram for embodying a moving block of the present embodiment;

FIG. 7 is a schematic structural diagram of a push plate embodying the present embodiment;

fig. 8 is a schematic structural diagram for embodying a material receiving plate according to the present embodiment.

Description of the reference numerals:

in the figure: 1. a transfer roll assembly; 11. a belt compression assembly; 12. a cutting assembly; 13. a first bracket; 131. a transfer roller; 132. a connecting plate; 133. a second bracket; 134. a rotating shaft; 135. a first transfer belt; 136. a first motor; 137. a vertical plate; 14. a first plate; 141. a second plate; 142. a first squeeze plate; 143. a second compression plate; 15. a first fixing lever; 151. a second fixing bar; 152. a first swing plate; 153. a second swing plate; 154. a first gear; 155. a second gear; 156. a rotating shaft; 157. a transition rod; 16. a drive wheel; 161. a chain; 162. a second transfer belt; 17. a transverse plate; 171. a rectangular frame; 172. a moving block; 173. moving the column; 174. a ball bearing; 175. a push rod; 176. pushing the plate; 177. a cylinder; 18. moving the hole; 181. a communicating hole; 182. a slider; 183. a first inclined surface; 184. a second inclined surface; 185. a first chute; 186. a second chute; 187. a support block; 1871. a roller; 19. a third support; 191. a material receiving plate; 192. a material cutting roller; 193. cutting the saw teeth; 194. and a fourth motor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

A cutting device for processing rock wool boards is shown in figures 1 and 2 and comprises a transmission roller assembly 1 for transmitting rock wool boards, a belt pressing assembly 11 arranged at one side of the transmission roller assembly 1, and a cutting assembly 12 arranged at one side of the belt pressing assembly 11;

as shown in fig. 1 and fig. 2, the conveying roller assembly 1 includes two first supports 13 oppositely disposed on the ground and a plurality of conveying rollers 131 rotatably connected to the two first supports 13, at this time, the first supports 13 are in an inverted U shape, that is, two vertical sides are fixed on the ground, each conveying roller 131 is rotatably disposed on a cross bar of the first support 13, each conveying roller 131 is located on the same plane, and a gap exists between adjacent conveying rollers 131, two first supports 13 are provided with a connecting plate 132 below the conveying rollers 131, that is, both ends of the connecting plate 132 are fixed to the two first supports 13, at this time, the first supports 13 are provided with extending rods extending vertically and downwardly on the horizontal portion, at this time, the connecting plate 132 is disposed on the extending rods, the connecting plate 132 is provided with a swinging member for swinging and straightening the rock wool plate above the conveying rollers 131, and the first supports 13 are provided with driving members for driving each conveying roller 131 to rotate; the straightening operation refers to pushing the rock wool boards obliquely placed on the conveying rollers 131 to a straightening position, and the straightening position refers to the distribution of the side edges of the rock wool boards along the length direction perpendicular to the conveying rollers 131.

As shown in fig. 1 and 2, the belt pressing assembly 11 includes two second brackets 133 which are arranged at the outlet of the transmission roller 131 and distributed oppositely, the second brackets 133 are inverted U-shaped plates, two ends of the two second brackets 133 are both rotatably provided with rotating shafts 134, the two rotating shafts 134 are connected through an annular first transmission belt 135, one of the second brackets 133 is provided with a first motor 136 which drives the rotating shafts 134 to rotate, at this time, the upper end surface of the first transmission belt 135 is flush with the upper end surface of the transmission roller 131, so as to transmit the rock wool plate to the first transmission belt 135, the upper ends of the two second brackets 133 are both provided with vertical plates 137, and a pressing member which presses the rock wool plate onto the first transmission belt 135 is arranged between the two vertical plates 137. The first motor 136 is configured to drive the first conveyor belt 135 to transport the rock wool panel to the cutting assembly 12 for cutting the rock wool panel.

If fig. 1 and fig. 2, the rock wool board that will treat cutting process is placed on transmission roller 131, each transmission roller 131 transmits the rock wool board to first transmission belt 135 this moment on, the piece of setting up in this process is ajusted the rock wool board and is set up, reduce the slope of rock wool board, improve the precision of rock wool board cutting, the rock wool board is set up the back at the rock wool board and is transmitted to first transmission belt 135 again, the setting that compresses tightly the piece makes the rock wool board compressed tightly, when the one end of rock wool board is transmitted out first transmission belt 135, cutting assembly 12 cuts the rock wool board of pair output, all the other rock wool boards are compressed tightly on first transmission belt 135 by the piece this moment, reduce the shake of rock wool board, when the cutting of rock wool board, it is fixed with the rock wool board, improve the cutting quality.

As shown in fig. 1 and 2, the straightening element includes a first plate 14 fixedly disposed on the connecting plate 132, and a second plate 141 slidably connected to the connecting plate 132, a moving direction of the second plate 141 moves along a length direction of the conveying rollers 131, that is, moves toward or away from the first plate 14, upper ends of the first plate 14 and the second plate 141 both extend out of an upper end of the conveying rollers 131, and a first pressing plate 142 and a second pressing plate 143 perpendicular to the length direction of the conveying rollers 131 are disposed at the extended ends respectively, a power element for driving the second plate 141 to move toward the first plate 14 is disposed on the connecting plate 132, and the first plate 14 and the second plate 141 extend to the upper end of the conveying rollers 131 through a gap between two adjacent conveying rollers 131.

As shown in fig. 1 and fig. 2, at this time, the power element drives the second plate 141 to move toward the first plate 14, so that the second extrusion plate 143 also moves toward the first extrusion plate 142, so that the rock wool plate located between the first extrusion plate 142 and the second extrusion plate 143 also moves toward the first extrusion plate 142, until the second extrusion plate 143 extrudes the rock wool plate on the first extrusion plate 142, so that two side edges of the rock wool plate respectively collide with the first extrusion plate 142 and the second extrusion plate 143, thereby realizing the rock wool plate straightening, at this time, the lower end surfaces of the transmission roller 131 and the rock wool plate roll and do not drive the rock wool plate to move together, and then the second extrusion plate 143 moves toward the direction away from the first extrusion plate 142, so that the transmission roller 131 continues to transmit the rock wool plate forward.

As shown in fig. 1 and 2, the connecting plate 132 includes two guide rods disposed on the two first brackets 13, the two guide rods are long along the length direction of the conveying roller 131, a first fixing rod 15 and a second fixing rod 151 are fixedly disposed between the two guide rods, that is, two ends of the second fixing rod 151 are slidably connected to the two guide rods, respectively, the power component includes a first swing plate 152 and a second swing plate 153 rotatably disposed on the first fixing rod 15 and the second fixing rod 151, respectively, the first swing plate 152 and the second swing plate 153 are rotatably disposed at one ends far away from the first fixing rod 15 and the second fixing rod 151, respectively, the first gear 154 and the second gear 155 are engaged with each other, the first gear 154 and the second gear 155 are rotatably connected to the positions where the first swing plate 152 and the second swing plate 153 are rotatably connected through a rotating shaft 156, one end of the rotating shaft 156 is fixed to the first swing plate 152 and the second swing plate 153, two ends of the two rotating shafts 156 are connected to one ends of the first gear 154 and the second swing plate 155 through a transition rod 157, the two ends of the two rotating shaft 157 are rotatably fixed to the first fixing rod 151, the second swing plate 151 is rotatably fixed to the first fixing rod 151, the second swing plate 151, and the second swing plate 151 is rotatably fixed to the second swing plate 141, and the second motor 14 is disposed on the two ends of the second swing plate 156.

As shown in fig. 1 and fig. 2, when the second motor drives the first swing plate 152 to rotate, the first swing plate 152 drives the first gear 154 to move along with the rotation of the first swing plate 152, at this time, the first gear 154 is engaged with the second gear 155 in the moving process along with the first swing plate 152, so that the first gear 154 and the second gear 155 rotate together, the arrangement of the transition rod 157 enables the first swing plate 152 to rotate in the direction away from the second fixing rod 151, the second swing plate 153 is driven to rotate through the transition rod 157, and the second fixing rod 151 is further driven to move in the direction close to the first fixing rod 15, otherwise, the second fixing rod 157 moves in the direction away from the first fixing rod 15, at this time, the second fixing rod 151 drives the second pressing plate 141 and the second pressing plate 143 above the second plate 141 to move in the direction of the first pressing plate 142, until the rock wool plate is pressed on the first pressing plate 142, at this time, the second motor stops rotating, and then the second motor reverses, and moves the second pressing plate 143 in the direction away from the first pressing plate 141, so that the rock wool plate 142 is conveniently transferred on the transfer roller 131.

As shown in fig. 1 and fig. 2, one end of each of the transmission rollers 131 extends out of one side of the first bracket 13, and a driving wheel 16 is coaxially disposed at the extended end, the driving member includes an annular chain 161 connected to each of the driving wheels 16, and a third motor for driving one of the transmission rollers 131 to rotate is disposed on the first bracket 13. The third motor can be located the first support 13 that does not set up chain 161, and when the third motor drove one of them transmission roller 131 to rotate, this transmission roller 131 drove each transmission roller 131 through drive wheel 16 and endless chain 161 and rotates, and then realized the transmission of rock wool board.

As shown in fig. 3, the pressing member includes a second transfer belt 162 disposed on the vertical plate 137, and when the rock wool panel is transferred on the first transfer belt 135, the transfer directions of the first transfer belt 135 and the second transfer belt 162 are the same. At this time, the second transmission belt 162 may be driven by a shaft rotatably disposed on the two vertical plates 137, and the rock wool boards are located between the second transmission belt 162 and the first transmission belt 135, so that when the first transmission belt 135 transmits the rock wool boards, the second transmission belt 162 also limits the rock wool boards on the first transmission belt 135, and at this time, the first transmission belt 135 and the second transmission belt 162 have the same length.

As shown in fig. 4 and fig. 6, or, the pressing member includes a horizontal plate 17 disposed between two vertical plates 137, the horizontal plate 17 is distributed along the length direction of the first transmission belt 135, a plurality of rectangular frames 171 are disposed on the horizontal plate 17 along the length direction of the horizontal plate 17, moving blocks 172 are connected in each rectangular frame 171 in a sliding manner, two moving columns 173 are connected in each moving block 172 in a sliding manner towards one end of the first transmission belt 135, balls 174 are embedded in each moving column 173 towards one end of the first transmission belt 135, a driving member for driving each moving block 172 to move up and down in the moving frame is disposed on the upper end of the horizontal plate 17, and when the driving member drives the moving block 172 to move down so that the moving column 173 collides with the rock wool board, a limiting member for limiting the position of the moving column 173 is disposed on the moving block 172.

As shown in fig. 4 and 6, when the rock wool board is transferred to the first transmission belt 135, the driving element drives the moving block 172 to move downwards so that the moving pillar 173 collides with the rock wool board, and the limiting element limits the position of the moving pillar 173 at this time, so that the moving pillar 173 limits the rock wool board on the first transmission belt 135, and at this time, as the rock wool board is transferred by the first transmission belt 135, each ball 174 enables the moving pillar 173 to roll with the rock wool board, thereby facilitating the moving and transferring of the rock wool board when the position of the rock wool board is limited.

As shown in fig. 4, 6 and 7, the driving member includes pushing rods 175 disposed at the upper end of each moving block 172, one end of each pushing rod 175 passes through the transverse plate 17 and is located above the transverse plate 17, one end of each pushing rod 175 passing through the transverse plate 17 is connected to one end of each pushing rod 176, and an air cylinder 177 for driving the pushing plates 176 to move up and down is disposed on the transverse plate 17. The cylinder 177 can extend and retract to drive the push plate 176 to move up and down, and further drive the push rod 175 to move up and down, so that the push rod 175 can drive each moving block 172 to move up and down in the rectangular frame 171.

As shown in fig. 4, 6 and 7, the limiting member includes a moving hole 18 formed in the moving block 172 and allowing the moving column 173 to move back and forth and up and down and a communicating hole 181 communicating with the two moving holes 18, the communicating hole 181 is located on one side of the moving hole 18 and is connected with a slider 182 in a sliding manner in the communicating hole 181, both ends of the slider 182 are provided with first inclined surfaces 183, that is, the first inclined surfaces 183 make the length of the slider 182 decrease and are distributed close to the moving hole 18, one end of the moving column 173 close to the slider 182 is provided with second inclined surfaces 184 matched with the first inclined surfaces 183, one end of the moving column 173 extends out of one side surface of the moving block 172 away from the transverse plate 17, each moving column 173 is provided with a first sliding groove 185 distributed along the length direction of the moving column 173, the slider 182 is provided with a second sliding groove 186 distributed along the length direction of the slider 182, and the moving block 172 is connected with a first rod entering the first sliding groove 185 and a second rod entering the second sliding groove 186 through threads.

As shown in fig. 4, 6 and 7, when the moving blocks 172 move toward the first transmission belt 135, the two moving pillars 173 of each moving block 172 abut against the rock wool panel, and if the upper end surface of the rock wool panel is uneven, the second inclined surfaces 184 of the two moving pillars 173 cooperate with the first inclined surfaces 183, so that the sliding blocks 182 move in the communicating holes 181 until the two moving pillars 173 stably abut against the upper end surface of the rock wool panel, thereby limiting the position of the rock wool panel on the first transmission belt 135.

Referring to fig. 5, the second support 133 is provided with a support block 187 for supporting the upper belt of the endless first belt 135 below the upper belt, a plurality of rollers 1871 are embedded in positions where the support block 187 contacts the upper belt of the first belt 135, a length direction of each roller 1871 is perpendicular to a conveying direction of the first belt 135, and each roller 1871 is distributed along the conveying direction of the first belt 135. The supporting blocks 187 are disposed at this time so that the rock wool panel is supported by the upper belt of the first transfer belt 135.

As shown in fig. 1 and 8, the cutting assembly 12 includes two opposite third brackets 19 disposed at the outlet of the first conveying belt 135, the third brackets 19 are plates disposed on the ground, a material receiving plate 191 is disposed between the two opposite third brackets 19, the two third brackets 19 are rotatably connected to the upper and lower ends of the material receiving plate 191 respectively, the lower material cutting roller 192 is disposed on one side of the upper material cutting roller 192 away from the first conveying belt 135, a plurality of cutting saw teeth 193 are disposed on the material receiving plate 192, an opening for the cutting saw teeth 193 of the lower material cutting roller 192 to extend out of the upper end surface of the material receiving plate 191 is disposed on the material receiving plate 191, the cutting saw teeth 193 of the two material cutting rollers 192 are correspondingly distributed, and a fourth motor 194 for driving the two material cutting rollers 192 to rotate is disposed on the third bracket 19.

As shown in fig. 1 and 8, the fourth motor 194 drives the two cutting rollers 192 to rotate for two, and at this time, the cutting saw teeth 193 on the cutting rollers 192 cut the rock wool panel, the cutting saw teeth 193 on the upper side cut the upper end of the rock wool panel, and the cutting saw teeth 193 on the lower side cut the lower end of the rock wool panel.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. The cutting device for processing the rock wool board is characterized by comprising a transmission roller assembly (1) for transmitting the rock wool board, a belt pressing assembly (11) arranged on one side of the transmission roller assembly (1), and a cutting assembly (12) arranged on one side of the belt pressing assembly (11);

the conveying roller assembly (1) comprises two first supports (13) which are oppositely arranged on the ground and a plurality of conveying rollers (131) which are rotatably connected to the two first supports (13), each conveying roller (131) is positioned on the same plane, a gap exists between every two adjacent conveying rollers (131), a connecting plate (132) is arranged below the conveying rollers (131) of the two first supports (13), namely two ends of the connecting plate (132) are fixed on the two first supports (13), a straightening piece for straightening rock wool boards above the conveying rollers (131) is arranged on the connecting plate (132), and a driving piece for driving each conveying roller (131) to rotate is arranged on each first support (13);

the belt compresses tightly subassembly (11) including setting up second support (133) in two relative distributions in transmission roller (131) export, two the both ends of second support (133) are all rotated and are equipped with axis of rotation (134), and two axis of rotation (134) are connected through annular first transmission belt (135), one of them be equipped with drive axis of rotation (134) pivoted first motor (136) on second support (133), two second support (133) upper end all is equipped with riser (137), two be equipped with between riser (137) and compress tightly the piece that compresses tightly the rock wool board on first transmission belt (135).

2. The cutting device for rock wool board processing of claim 1, wherein the straightening element includes a first plate (14) fixedly arranged on the connecting plate (132) and a second plate (141) connected to the connecting plate (132) in a sliding manner, the moving direction of the second plate (141) moves along the length direction of the conveying roller (131), the upper ends of the first plate (14) and the second plate (141) both extend out of the upper end of the conveying roller (131) and are respectively provided with a first pressing plate (142) and a second pressing plate (143) perpendicular to the length direction of the conveying roller (131), the connecting plate (132) is provided with a power element for driving the second plate (141) to move towards the first plate (14), and the first plate (14) and the second plate (141) extend to the upper end of the conveying roller (131) through a gap between two adjacent conveying rollers (131).

3. The cutting device for rock wool panel processing as claimed in claim 2, wherein the connecting plate (132) comprises two guide rods arranged on the two first brackets (13), the length direction of the two guide rods is along the length direction of the transmission roller (131), a first fixing rod (15) and a second fixing rod (151) are fixedly arranged between the two guide rods, the power member comprises a first swing plate (152) and a second swing plate (153) rotatably arranged on the first fixing rod (15) and the second fixing rod (151), respectively, the first swing plate (152) and the second swing plate (153) are rotatably arranged at one ends far away from the first fixing rod (15) and the second fixing rod (151), respectively, a first gear (154) and a second gear (155) are rotatably arranged on the first swing plate (152) and the second swing plate (151), the first gear (154) and the second gear (155) are engaged with each other, the first gear (154) and the second gear (155) are rotatably connected with the first swing plate (152) and the second swing plate (153) through a rotating shaft (156), the first gear (156) and the second gear (157) is rotatably connected with the second swing plate (157) through the rotating shaft (157), and the second swing plate (157) is connected with the second swing plate (157) through the rotating shaft (157), the first plate (14) is fixed on a first fixing rod (15), the second plate (141) is fixed on a second fixing rod (151), and a second motor for driving the first swing plate (152) to rotate is arranged on the first fixing rod (15).

4. The cutting device for rock wool board processing as claimed in claim 1, wherein one end of each transmission roller (131) all extends out of a side surface of the first support (13) and is provided with a driving wheel (16) coaxially at the extended end, the driving member comprises an annular chain (161) connected with each driving wheel (16), and the first support (13) is provided with a third motor for driving one of the transmission rollers (131) to rotate.

5. The cutting device for rock wool board processing as claimed in claim 1, wherein, the pressing member includes a second transmission belt (162) arranged on the vertical plate (137), when the rock wool board is transmitted on the first transmission belt (135), the transmission directions of the first transmission belt (135) and the second transmission belt (162) are consistent.

6. The cutting device for rock wool plate processing as claimed in claim 1, wherein the pressing member comprises a horizontal plate (17) disposed between two vertical plates (137), the horizontal plate (17) is distributed along the length direction of the first transmission belt (135), a plurality of rectangular frames (171) are disposed on the horizontal plate (17) along the length direction of the horizontal plate (17), each rectangular frame (171) is connected with a moving block (172) in a sliding manner, one end of each moving block (172) facing the first transmission belt (135) is connected with two moving columns (173) in a sliding manner, one end of each moving column (173) facing the first transmission belt (135) is embedded with a ball (174), a driving member for driving each moving block (172) to move up and down in the moving frame is disposed at the upper end of the horizontal plate (17), and when the driving member drives the moving blocks (172) to move down so that the moving columns (173) abut against the rock wool plate, a limiting member for limiting the position of the moving columns (173) is disposed on the moving blocks (172).

7. The cutting device for rock wool plate processing as claimed in claim 6, wherein said driving means includes pushing rods (175) disposed at the upper end of each moving block (172), one end of each pushing rod (175) passes through the transverse plate (17) and is located above the transverse plate (17), one end of each pushing rod (175) passing through the transverse plate (17) is connected through a pushing plate (176), and the transverse plate (17) is provided with a cylinder (177) for driving the pushing plate (176) to move up and down.

8. The cutting device for rock wool board processing as claimed in claim 7, wherein the limiting member includes a moving hole (18) provided on a moving block (172) and used for the moving column (173) to move back and forth and up and down and a communicating hole (181) communicated with the two moving holes (18), the communicating hole (181) is located at one side of the moving hole (18) and connected with a sliding block (182) in the communicating hole (181) in a sliding manner, both ends of the sliding block (182) are provided with first inclined surfaces (183), one end of the moving column (173) close to the sliding block (182) is provided with second inclined surfaces (184) matched with the first inclined surfaces (183), one end of the moving column (173) extends out of a side surface of the moving block (172) away from the transverse plate (17), each moving column (173) is provided with first sliding grooves (185) distributed along the length direction of the moving column (173), the sliding block (182) is provided with second sliding grooves (186) distributed along the length direction of the sliding block (182), and the moving block (172) is connected with a first sliding groove (185) and a second sliding groove (186) rod (183) which enters the first sliding groove (183) and the second sliding groove (186) in the first sliding groove (183).

9. The cutting device for rock wool board processing as claimed in claim 8, wherein the second bracket (133) is provided with a supporting block (187) for supporting the upper belt under the upper belt of the first endless conveying belt (135), a plurality of rollers (1871) are embedded in the position where the supporting block (187) contacts with the upper belt of the first endless conveying belt (135), the length direction of each roller (1871) is distributed perpendicular to the conveying direction of the first endless conveying belt (135), and each roller (1871) is distributed along the conveying direction of the first endless conveying belt (135).

10. The cutting device for rock wool board processing as claimed in claim 1, wherein said cutting assembly (12) includes two opposite third brackets (19) disposed at the outlet of the first transmission belt (135), a material receiving plate (191) is disposed between the two opposite third brackets (19), and the two third brackets (19) are respectively rotatably connected to the upper and lower ends of the material receiving plate (191) by material cutting rollers (192), said material cutting rollers (192) are disposed with a plurality of cutting saw teeth (193), said material receiving plate (191) is disposed with an opening for the cutting saw teeth (193) on the material cutting rollers (192) below to extend out of the upper end surface of the material receiving plate (191), the cutting saw teeth (193) on the two material cutting rollers (192) are correspondingly distributed, and said third brackets (19) are disposed with a fourth motor (194) for driving the two material cutting rollers (192) to rotate.

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