CN211306450U

CN211306450U - Energy-efficient perpendicular silk cutting machine for rock wool composite sheet production

Info

Publication number: CN211306450U
Application number: CN201921967273.8U
Authority: CN
Inventors: 杨万涛
Original assignee: Hebei Novartis Xinrong Energy Saving Technology Co ltd
Current assignee: Hebei Novartis Xinrong Energy Saving Technology Co ltd
Priority date: 2019-11-14
Filing date: 2019-11-14
Publication date: 2020-08-21
Anticipated expiration: 2029-11-14

Abstract

The utility model discloses a cutting machine for producing high-efficiency energy-saving vertical-filament rock wool composite boards, which relates to the technical field of rock wool composite board production, wherein a processing platform is jointly installed on the top end surface of a bearing stand column of four devices, a plurality of bearing frames which are distributed at equal intervals are fixedly installed on the top end surface of the processing platform, X axial moving mechanisms are jointly installed on two sides of the processing platform, a slidable Y axial moving cutting mechanism is installed at the sliding end on the back surface of the X axial moving mechanism, the X axial moving mechanism realizes transmission in a way of mutual meshing of gears and gear grooves, the Y axial moving cutting mechanism realizes transmission in a way of screw rod transmission, when in normal cutting, an operator only needs to control the opening and closing of a motor, the automatic adjustment of a cutting part of the cutting machine can be completed, compared with the manual adjustment mode adopted by the cutting part in the prior, and the working efficiency of the cutting machine can be greatly improved, and the practicability is improved.

Description

Energy-efficient perpendicular silk cutting machine for rock wool composite sheet production

Technical Field

The utility model relates to a rock wool composite sheet production technical field specifically is a cutting machine is used in production of energy-efficient vertical filament rock wool composite sheet.

Background

The rock wool board is made up by using stone such as basalt, iron ore and bauxite as main raw material, and adding proper quantity of binder through the process of high-temp. melting treatment so as to obtain the invented artificial inorganic fibre with the characteristics of light weight, small heat conductivity, heat-absorbing and non-inflammable. The rock wool board which is successfully tested in 4 months in 1976 is a novel heat-preservation, fire-insulation and sound-absorption material, and the finished rock wool composite board needs to be cut according to the requirements of customers in the production process of the rock wool composite board, and the process needs to be completed by means of a board cutting machine.

But at present, the cutting machine that current rock wool composite sheet used in cutting process, at the in-process of in-service use, in order to reach better cutting effect, the position of the cutting part on the cutting machine need be adjusted, and prior art needs the manual work to accomplish the regulation with the help of the hand wheel usually, the holistic cutting efficiency of cutting machine has been reduced, and waste time and energy, and the operation cutting machine needs two or more staff even, the manufacturing cost of rock wool composite sheet has been improved, for this reason, technical personnel in the field have proposed a high-efficient energy-conserving vertical filament rock wool composite sheet production and have used cutting machine.

SUMMERY OF THE UTILITY MODEL

The utility model provides a not enough to prior art, the utility model provides a cutting machine is used in production of energy-efficient vertical filament rock wool composite sheet has solved the position of the cutting part on the cutting machine and needs to adjust, and prior art needs the manual work to accomplish the regulation with the help of the hand wheel usually, has reduced the holistic cutting efficiency of cutting machine, wastes time and energy moreover, and the operation cutting machine needs two staff even more, has improved the manufacturing cost's of rock wool composite sheet problem.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides a cutting machine is used in production of energy-efficient perpendicular silk rock wool composite sheet, bears the stand, per two including four equipment of equal height the equipment bears a fixed reinforcement crossbeam of welding between the stand, a processing platform is installed jointly to the top terminal surface that four equipment bore the stand, the top terminal surface fixed mounting of processing platform has the bearing frame that a plurality of equidistance distribute, X axial displacement mechanism is installed jointly to the both sides of processing platform, slidable Y axial displacement cutting mechanism is installed to the slip end at the X axial displacement mechanism back.

Preferably, the X axial moving mechanism includes two sets of first slide rails and second slide rails respectively fixedly mounted on end surfaces on two sides of the processing platform, and a first bearing vertical plate and a second bearing vertical plate which are arranged at outer end portions of the first slide rails and the second slide rails through a plurality of limiting rubber wheels, and the plurality of limiting rubber wheels are respectively fixedly mounted at end surfaces adjacent to the first slide rails and the second slide rails.

Preferably, a first servo motor is fixedly installed in the middle of the outer end face of the second bearing vertical plate, the output end of the first servo motor extends to the inner side face of the second bearing vertical plate, a driving gear is fixedly installed on the inner side face of the first bearing vertical plate, and a reinforcing linkage plate is welded to the top end faces of the first bearing vertical plate and the second bearing vertical plate together.

Preferably, the end faces of the bottoms of the two groups of second sliding rails are provided with a row of gear grooves matched with the driving gear for use, and the transmission ratio between the gear grooves and the driving gear is 1: 1.

Preferably, Y axial displacement cutting mechanism includes two runways of fixed mounting at X axial displacement mechanism top back, the slip end of two runways has a support plate through the runway wheelset slidable mounting of four group rectangle distributions, the central point of the adjacent terminal surface of support plate and runway puts fixed mounting has a silk section of thick bamboo, the inside of a silk section of thick bamboo has a lead screw parallel with the runway through connection of screw thread, the pot head of lead screw is equipped with spacing bearing frame, and the other end fixed drive end that has concatenated the second servo motor of lead screw.

Preferably, the upper end and the lower end of the support plate are respectively connected with an upper rubbing plate and a lower rubbing plate in a hinged manner, a driving motor is fixedly installed on the top end face of the upper rubbing plate, and a driving belt wheel is fixedly sleeved on the driving end of the driving motor.

Preferably, two bearing seats are symmetrically installed on the top end face of the lower expansion plate, a transmission shaft is connected to the rotating portions inside the two bearing seats, one end of the transmission shaft extends to the outer side of one of the bearing seats, a driven pulley is fixedly sleeved on the transmission shaft, the other end of the transmission shaft extends to the outer side of the other bearing seat, and a saw disc is fixedly installed on the transmission shaft.

Preferably, the second servo motor is fixedly mounted on one side of the top of the X-axis moving mechanism through a Z-shaped motor mounting seat, the bottom end face of the upper rubbing plate and the top end face of the lower rubbing plate are connected with an angle adjusting rod together, and two ends of the angle adjusting rod are respectively hinged with the upper rubbing plate and the lower rubbing plate

Preferably, two transmission belts are sleeved outside the driven belt wheel and the driving belt wheel together, and the transmission ratio of the driven belt wheel to the driving belt wheel is 1: 1.

Advantageous effects

The utility model provides a cutting machine is used in production of energy-efficient vertical filament rock wool composite sheet. Compared with the prior art, the method has the following beneficial effects:

1. this energy-efficient erects silk cutting machine for rock wool composite sheet production, install X axial displacement mechanism jointly through the both sides at the processing platform, slidable Y axial displacement cutting mechanism is installed to the slip end at the X axial displacement mechanism back, wherein, X axial displacement mechanism realizes the transmission through gear and gear groove intermeshing's mode, and Y axial displacement cutting mechanism realizes the transmission through the mode of lead screw conveying, when normal cutting, operating personnel only need opening and close of control motor, can accomplish the automatically regulated of cutting machine cutting part, compare cutting part adoption manual regulation mode among the prior art, this mode is labour saving and time saving more, and can increase substantially the work efficiency of cutting machine, and the high practicality is improved.

2. This cutting machine is used in production of energy-efficient perpendicular silk rock wool composite sheet, X axial displacement mechanism and Y axial displacement cutting mechanism rely on rubber tyer and slide rail and the spacing block of runway wheelset and runway at the in-process of position adjustment for whole adjustment process is steady more, and is safe, structure scientific and reasonable, convenience safe in utilization.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural view of the X-axis moving mechanism of the present invention;

fig. 3 is a schematic structural view of a second slide rail of the present invention;

fig. 4 is a schematic structural diagram of the Y axial movement cutting mechanism of the present invention.

In the figure: 1. the equipment bears the weight of the pillar; 2. reinforcing the cross beam; 3. a processing platform; 4. a load-bearing frame; 5. an X-axis moving mechanism; 51. a first bearing vertical plate; 52. a second bearing vertical plate; 53. a limiting rubber wheel; 54. a first slide rail; 55. a second slide rail; 56. a gear groove; 57. a first servo motor; 58. a drive gear; 59. reinforcing the linkage plate; 6. moving the cutting mechanism in the Y-axis direction; 61. a runway; 62. a carrier plate; 63. a runway wheel set; 64. a wire barrel; 65. a screw rod; 66. a limiting bearing seat; 67. a second servo motor; 68. a motor mounting seat; 69. an upper rubbing plate; 610. a lower rubbing plate; 611. a drive motor; 612. a driving pulley; 613. a bearing seat is carried; 614. a drive shaft; 615. a driven pulley; 616. sawing a disc; 617. an angle adjusting rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a cutting machine is used in production of energy-efficient perpendicular silk rock wool composite sheet, bear stand 1 including four equal-height equipment, every two equipment bear a fixed reinforcement crossbeam 2 between the stand 1, a processing platform 3 is installed jointly to the top terminal surface that four equipment bore stand 1, the top terminal surface fixed mounting of processing platform 3 has the bearing frame 4 that a plurality of equidistance distribute, X axial displacement mechanism 5 is installed jointly to the both sides of processing platform 3, slidable Y axial displacement cutting mechanism 6 is installed to the sliding end at the 5 backs of X axial displacement mechanism.

Referring to fig. 2-3, the X-axis moving mechanism 5 includes two sets of first and second sliding

rails

54 and 55 respectively fixedly mounted on the end surfaces of the two sides of the processing platform 3, and a first and second supporting

upright plates

51 and 52 respectively fixedly mounted on the outer end portions of the first and second sliding

rails

54 and 55 through a plurality of limiting rubber wheels 53, the plurality of limiting rubber wheels 53 are respectively fixedly mounted on the end surfaces adjacent to the first and second sliding

rails

54 and 55, a first servo motor 57 is fixedly mounted on the middle position of the outer end surface of the second supporting upright plate 52, the output end of the first servo motor 57 extends to the inner side surface of the second supporting upright plate 52, and a driving gear 58 is fixedly mounted on the inner side surface of the first supporting upright plate 51, a reinforcing linkage plate 59 is welded together on the top end surfaces of the first and second supporting

upright plates

51 and 52, a row of gear grooves 56 matched with the driving gear 58 is formed on the bottom end surfaces of the two sets of the second sliding rails 55, the gear ratio between gear groove 56 and drive gear 58 is 1: 1.

Referring to fig. 4, the Y-axis moving and cutting mechanism 6 includes two runways 61 fixedly mounted on the back of the top of the X-axis moving mechanism 5, a support plate 62 is slidably mounted at the sliding end of the two runways 61 through four sets of rectangularly distributed runway wheel sets 63, a screw cylinder 64 is fixedly mounted at the center position of the end surface of the support plate 62 adjacent to the runways 61, a screw rod 65 parallel to the runways 61 is penetratingly connected inside the screw cylinder 64 through a screw thread, a limit bearing seat 66 is sleeved at one end of the screw rod 65, the other end of the screw rod 65 is fixedly connected in series with a driving end of a second servo motor 67, an upper end and a lower end of the support plate 62 are respectively connected with an upper rubbing plate 69 and a lower rubbing plate 610 in a hinged manner, a driving motor 611 is fixedly mounted on the top end surface of the upper rubbing plate 69, a driving pulley 612 is fixedly secured at the driving end of, the rotating parts inside the two bearing seats 613 are connected with a transmission shaft 614, one end of the transmission shaft 614 extends to the outer side of one bearing seat 613, a driven pulley 615 is fixedly sleeved and connected with the transmission shaft, the other end of the transmission shaft 614 extends to the outer side of the other bearing seat 613, a saw disc 616 is fixedly installed on the transmission shaft, two transmission belts are sleeved on the driven pulley 615 and the outer part of the driving pulley 612, the transmission ratio of the driven pulley 615 to the driving pulley 612 is 1:1, the second servo motor 67 is fixedly installed on one side of the top of the X axial movement mechanism 5 through a zigzag motor installation seat 68, the bottom end face of the upper rubbing plate 69 and the top end face of the lower rubbing plate 610 are connected with an angle adjusting rod 617, and two ends of the angle adjusting rod 617 are respectively hinged with the upper rubbing plate 69 and the lower rubbing plate 610.

When in use, the rock wool composite board to be cut is placed above the bearing frame 4, then the rock wool composite board is cut according to the size required by a customer, when in cutting, the position of the saw disc 616 needs to be adjusted, at the moment, when in adjustment along the long side of the processing platform 3, the first servo motor 57 is started, the first servo motor 57 directly drives the driving gear 58 to rotate, because the driving gear 58 is meshed with the gear groove 56 on the end surface of the bottom of the second slide rail 55, and the second slide rail 55 is fixed on the two sides of the processing platform 3, the action of the first slide rail 54 is combined with the action of the force, the rotation of the first servo motor 57 indirectly drives the self-movement, therefore, the reinforcing linkage plate 59 drives the Y-axis moving cutting mechanism 6 to integrally move along the long side of the processing platform 3, and similarly, when in adjustment along the short side of the processing platform 3, the second servo motor 67 is started, the second servo motor 67 drives the screw rod 65 to rotate, the screw rod 65 is connected with the screw tube 64 through a thread, and the screw tube 64 is fixedly installed on the support plate 62, therefore, the support plate 62 can move along the direction of the screw rod 65 by the rotation of the screw rod 65, the saw disc 616 is installed on the top of the lower expanding plate 610 hinged with the support plate 62, therefore, the saw disc 616 is synchronously moved together with the saw disc 616, the position of the saw disc 616 can be respectively adjusted by the two methods, then, the driving motor 611 is started, the driving motor 611 drives the driving pulley 612 to rotate, the driving pulley 612 drives the driven pulley 615 to rotate under the action of the transmission belt, the driven pulley 615 directly drives the transmission shaft 614 to rotate under the action of the bearing pedestal 613, the transmission shaft 614 drives the saw disc 616 to rotate, thereby realizing the cutting treatment of the rock wool composite board, and having scientific and reasonable structure, the use is safe and convenient.

In the present embodiment, the first servo motor 57 and the second servo motor 67 can support forward and reverse rotation, both of which are made of SMG80-M02430, and the driving motor 611 is made of 1TL0001, and in the above components, the structural features and the operation principle thereof, as well as the specific circuit structure electrically connected with the outside, are made of the prior art, and will not be described in detail herein.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a cutting machine is used in production of energy-efficient vertical filament rock wool composite sheet, includes that equipment such as four are high bears stand (1), its characterized in that: every two equipment bears a fixed reinforcement crossbeam (2) of welding between stand (1), a processing platform (3) is installed jointly to the top terminal surface that four equipment bore stand (1), the top terminal surface fixed mounting of processing platform (3) has a plurality of equidistance bearing frame (4) that distribute, X axial displacement mechanism (5) are installed jointly to the both sides of processing platform (3), slidable Y axial displacement cutting mechanism (6) are installed to the sliding end at X axial displacement mechanism (5) back.

2. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 1 is characterized in that: the X-axis moving mechanism (5) comprises two groups of first sliding rails (54) and second sliding rails (55) which are fixedly mounted on the end faces of the two sides of the machining platform (3) respectively, and a first bearing vertical plate (51) and a second bearing vertical plate (52) which are arranged at the outer end portions of the first sliding rails (54) and the second sliding rails (55) through a plurality of limiting rubber wheels (53) in a clamping mode, wherein the plurality of limiting rubber wheels (53) are fixedly mounted on the end faces of the first sliding rails (54) and the second sliding rails (55) which are adjacent to each other respectively.

3. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 2 is characterized in that: a first servo motor (57) is fixedly mounted in the middle of the outer end face of the second bearing vertical plate (52), the output end of the first servo motor (57) extends to the inner side face of the second bearing vertical plate (52), a driving gear (58) is fixedly mounted on the inner side face of the first bearing vertical plate (51), and a reinforcing linkage plate (59) is welded to the top end faces of the first bearing vertical plate (51) and the second bearing vertical plate (52) together.

4. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 3 is characterized in that: the end faces of the bottoms of the two groups of second sliding rails (55) are provided with a row of gear grooves (56) matched with the driving gear (58) for use, and the transmission ratio between the gear grooves (56) and the driving gear (58) is 1: 1.

5. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 1 is characterized in that: y axial displacement cutting mechanism (6) include two runways (61) of fixed mounting at X axial displacement mechanism (5) top back, the slip end of two runways (61) has a support plate (62) through runway wheelset (63) slidable mounting of four groups rectangle distributions, the central point of support plate (62) and the adjacent terminal surface of runway (61) puts fixed mounting has a silk section of thick bamboo (64), the inside of silk section of thick bamboo (64) has a lead screw (65) parallel with runway (61) through the screw thread through connection, the pot head of lead screw (65) is equipped with spacing bearing frame (66), and the fixed drive end that has concatenated second servo motor (67) of the other end of lead screw (65).

6. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 5 is characterized in that: the upper end and the lower end of the support plate (62) are respectively connected with an upper rubbing plate (69) and a lower rubbing plate (610) in a hinged mode, the top end face of the upper rubbing plate (69) is fixedly provided with a driving motor (611), and the driving end of the driving motor (611) is fixedly sleeved with a driving belt wheel (612).

7. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 6 is characterized in that: two bearing seats (613) are symmetrically installed on the top end face of the lower rubbing plate (610), the rotating parts in the two bearing seats (613) are connected with a transmission shaft (614), one end of the transmission shaft (614) extends to the outer side of one bearing seat (613), a driven pulley (615) is fixedly sleeved on the transmission shaft, the other end of the transmission shaft (614) extends to the outer side of the other bearing seat (613), and a saw disc (616) is fixedly installed on the transmission shaft.

8. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 7 is characterized in that: the second servo motor (67) is fixedly installed on one side of the top of the X-axis moving mechanism (5) through a Z-shaped motor installation seat (68), the bottom end face of the upper rubbing plate (69) and the top end face of the lower rubbing plate (610) are connected with an angle adjusting rod (617) together, and two ends of the angle adjusting rod (617) are hinged to the upper rubbing plate (69) and the lower rubbing plate (610) respectively.

9. The cutting machine for producing the high-efficiency energy-saving vertical-wire rock wool composite board according to claim 7 is characterized in that: two transmission belts are sleeved outside the driven belt wheel (615) and the driving belt wheel (612) together, and the transmission ratio of the driven belt wheel (615) to the driving belt wheel (612) is 1: 1.