CN114701056A - Heat-insulation building block processing system and method for building engineering construction - Google Patents

Abstract

The invention relates to a system and a method for processing heat-insulating building blocks for construction of constructional engineering, which comprises a base, supporting side plates and a supporting top plate, wherein the supporting side plates are arranged on the left side and the right side of the upper end of the base and are symmetrically distributed in the front and back direction; the invention can solve the following problems in the process of producing the heat-preservation aerated building block in the prior art: the gaps of the heat-preservation aerated building blocks are small, so that the consumption of raw materials is large, and the sound insulation and heat insulation performance of the heat-preservation aerated building blocks is reduced; the cutting heat preservation aerated building block needs to be provided with a large-scale cutting machine, the cutting machine usually occupies a large area, the required cost is high during purchase, use and maintenance, and the cutting process is complicated.

Description

Heat-insulation building block processing system and method for building engineering construction

Technical Field

The invention relates to the field of heat-insulating block processing, in particular to a system and a method for processing heat-insulating blocks for building engineering construction.

Background

The heat-insulating building block is used as non-bearing wall building material. The heat-insulating building block comprises a composite self-heat-insulating building block, an aerated concrete building block and the like, wherein the aerated concrete building block is a novel wall material prepared by taking stone powder, cement and lime as main raw materials through raw material preparation, pouring, cutting and forming and high-pressure steam curing. The method is mainly applied to non-bearing wall masonry and frame structure filling.

The gaps in the existing aerated concrete blocks are mainly formed by curing raw materials through high-pressure steam, the aerated concrete blocks before and after curing need to be cut, and with the technical progress, technical personnel in related fields also optimize the production process of the aerated concrete blocks.

In order to ensure accurate corresponding proportion, chinese patent publication No. CN205097374U discloses an aerated brick cutting device, in which an oil cylinder is started to push a support plate downward, a hook hooks an aerated brick in an aerated brick fermentation tank, the support plate is pulled upward by the oil cylinder to lift the aerated brick, a power device pushes a slide block to move forward on a linear guide rail to a position above a cutting machine, the oil cylinder pushes the support plate to move downward again, the aerated brick is placed on the upper end surface of the cutting machine, and a rotary disc type cutter is used to cut the aerated brick.

However, the above prior art has the following technical drawbacks: 1. because the air-entrapping gap inside the existing air-entrapping building block is smaller, the consumption of building block raw materials with a certain size is more in the process of producing the air-entrapping building block; the small air-entrapping gap also reduces the sound and heat insulation performance of the air-entrapping building block.

2. The aerated building block is required to be cut by a large-scale cutting machine, the cutting machine usually occupies a large area, the cost required during purchase, use and maintenance is high, and the cutting process of the aerated building block is complicated; and a large amount of waste leftover materials are cut off, so that the production cost of the aerated building block is increased.

Disclosure of Invention

In order to solve the problems, the invention provides a heat insulation block processing system for building engineering construction, which comprises a base, supporting side plates and a supporting top plate, wherein the supporting side plates are arranged on the left side and the right side of the upper end of the base and are symmetrically distributed in the front and back direction, the supporting top plate is arranged between the upper ends of the supporting side plates, an inflating mechanism for inflating heat insulation blocks is arranged on the supporting top plate, a cover plate mechanism for shielding the upper ends of the heat insulation blocks is arranged on the lower side of the inflating mechanism, a die mechanism for bearing heat insulation block raw materials is arranged between the supporting side plates and on the lower side of the cover plate mechanism, and a transmission mechanism for bearing the heat insulation blocks is arranged between the supporting side plates and on the lower side of the die mechanism.

The air inflation mechanism comprises a lifting cylinder and a mounting plate, wherein the lifting cylinder is mounted at the lower end of the middle part of the supporting top plate, the mounting plate is arranged at the lower end of the lifting cylinder, adjusting branched chains for up-and-down adjustment are arranged at the front end and the rear end of the mounting plate, a hollow exhaust plate adjusted by the adjusting branched chains is arranged at the lower end of the adjusting branched chains, the hollow exhaust plate is provided with a connecting cylinder for communicating with an air pump, exhaust cylinders communicated with the hollow exhaust plate and used for inflating the heat-insulation building blocks are uniformly arranged at the lower end of the hollow exhaust plate, and check valves for preventing raw materials from entering the exhaust cylinders are arranged at the lower ends of the exhaust cylinders;

the die mechanism including set up between the support curb plate and be used for carrying out the bearing case that the bearing was accomodate to the insulation block raw materials to and set up and be used for carrying out the electric heat net rack that the interval made its formation building block shape to the insulation block raw materials in bearing incasement portion.

By adopting the technical scheme, the mold mechanism can bear and separate the heat-preservation building block raw material after being allocated and stirred to enable the heat-preservation building block raw material to form a shape of a building block, and then the heat-preservation building block raw material is communicated with an external inert gas inflation machine through a connecting cylinder, the inflation mechanism can carry out multi-point inert gas inflation processing on the raw material in the mold mechanism, the upper end of the raw material is heated through the cover plate mechanism so as to accelerate solidification of the raw material, after the raw material is solidified into the building block, the cover plate mechanism moves upwards to reset, the mold mechanism overturns for one hundred eighty degrees through the mold mechanism, the conveying mechanism moves upwards to the lower side of the mold mechanism, the mold mechanism enables the mold mechanism to demould the building block, the demould building block after demould drops to the upper end of the conveying mechanism, then the conveying mechanism resets downwards, and the conveying mechanism conveys the building block to one side.

Preferably, the adjusting branched chain comprises a lifting rack, a gear rod, a transmission gear, a rotating motor, a limiting cylinder and a limiting fixture block, wherein the lifting rack is symmetrically arranged on the mounting plate in a front-back sliding fit mode, the lower end of the lifting rack is connected with the hollow exhaust plate, a gear groove is formed in the mounting plate and is positioned on the opposite side of the lifting rack, the gear rod is arranged in the gear groove in a rotating fit mode, the transmission gear meshed with the lifting rack is arranged on the outer side surface of the gear rod, the right end of the gear rod penetrates through the mounting plate and is connected with an output shaft of the rotating motor, the rotating motor is connected with the mounting plate through a motor base, cylinder grooves are symmetrically formed in the front end and the rear end of the mounting plate, the limiting cylinder is arranged in the cylinder groove, and the telescopic end on the opposite side of the limiting cylinder is provided with the limiting fixture block corresponding to the transmission gear; through adopting above-mentioned technical scheme, inside the back of the raw materials in the aiutage inserts the mould mechanism, adjust the branch chain and can drive the aiutage upwards to carry out indirect removal to make the aiutage can discharge appropriate amount of inert gas to the different positions in the raw materials in proper order.

Preferably, the cover plate mechanism comprises a driven plate, a first lead screw, a rotating motor, a 21274, a first shape connecting plate, a top cover upper plate, an electric heating plate, a material blocking upper plate and a push-pull cylinder, wherein the driven plate is arranged between the supporting side plates on the front side and the rear side in a vertical sliding fit mode, the first lead screw is arranged in the middle of the left driven plate in a thread fit mode, the upper end of the first lead screw penetrates through the supporting top plate and is connected with an output shaft of the rotating motor, the rotating motor is arranged at the upper end of the supporting top plate through a motor seat, the 21274is arranged on the opposite sides of the left driven plate and the right driven plate, the first shape connecting plate and the 21274are connected through the top cover upper plate, the electric heating plate is arranged on the lower side surface of the top cover upper plate, penetrating rod through holes corresponding to the exhaust pipes are formed between the top cover upper plate and the electric heating plate, a baffle groove is formed in the top cover upper plate, the material blocking upper plate is arranged in the baffle groove in a sliding fit mode, circular through holes corresponding to the penetrating rod through holes are also formed in the material blocking upper plate, one side of the upper baffle plate is connected with the side wall of the baffle groove through a push-pull cylinder; through adopting above-mentioned technical scheme, can cover mould mechanism upper end under the circumstances that does not hinder aerifing the mechanism to thereby it heats the solidification process of accelerating the raw materials.

Preferably, the mould mechanism still include fixed block, driven bull stick, upset branch chain, reciprocal branch chain, stock branch chain and scrape the material branch chain, all be provided with the fixed block between the curb plate is supported to both sides around, the fixed block middle part all is provided with driven bull stick through normal running fit's mode, the right-hand member of the driven bull stick on right side is provided with the upset branch chain, the opposite side of the driven bull stick of the left and right sides passes through the bearing case and connects, be provided with reciprocal branch chain on the lateral wall of bearing case, the inside stock branch chain that is provided with of bearing case, bearing case upper end is provided with scrapes the material branch chain.

By adopting the technical scheme, the heat-preservation building block raw material after being mixed and stirred can be supported and separated; firstly, placing a raw material in a material storage branched chain, heating a part of the raw material in contact with the raw material through the material storage branched chain, so that the edge of a building block can be solidified firstly, then inserting the raw material into the lower side of the raw material through an inflating mechanism, intermittently moving upwards through the inflating mechanism, intermittently injecting inert gas into the raw material in the process, after the raw material is inflated, moving upwards through the inflating mechanism to reset, then scraping the upper end of the raw material through a material scraping branched chain, downwards pressing the upper end of the raw material through a cover plate mechanism and heating the raw material, after the surface of the raw material is solidified, driving the material storage branched chain and the building block to shake back and forth through a reciprocating branched chain, so that the inert gas in the building block can be shaken uniformly, after the building block is completely solidified, moving upwards through the cover plate mechanism to reset, driving a bearing box to rotate by one hundred eighty degrees through a turning branched chain, then, the transmission mechanism moves upwards to the lower side of the building block, demolding is conducted on the building block through the material storage branched chain, the building block can drop downwards to the upper end of the transmission mechanism, then the transmission mechanism drives the building block to reset downwards, and finally the transmission mechanism drives the building block to transmit to one side.

Preferably, the turning branched chain comprises a rotating gear, a driving cylinder and a driven rack, the right end of the driven rotating rod on the right side penetrates through the fixed block and is provided with the rotating gear, the lower side of the fixed block on the right side is provided with the driving cylinder through a cylinder seat, and the upper end of the driving cylinder is provided with the driven rack meshed with the rotating gear; through adopting above-mentioned technical scheme, can drive the bearing case and carry out one hundred eighty degrees upsets to be convenient for carry out the drawing of patterns to the building block.

Preferably, the reciprocating branch chain comprises a connecting rotating rod, an elliptical block, a motor I and a reset pressure spring rod, a rotating through groove is uniformly formed in the front side surface of the bearing box, the middle part of the rotating through groove is connected in a rotating fit mode through the connecting rotating rod, the elliptical block is arranged in the rotating through groove on the outer side surface of the connecting rotating rod, the outer side surface of the elliptical block is attached to the material storage branch chain, a motor groove is formed in the right end of the connecting rotating rod of the bearing box, the motor I is arranged in the motor groove through a motor base, the output shaft of the motor I is connected with the connecting rotating rod, the reset pressure spring rod is arranged on the rear side wall of the bearing box, and the front end of the reset pressure spring rod is connected with the material storage branch chain; by adopting the technical scheme, the material storage branched chain can be driven to reciprocate back and forth, so that inert gas in the raw material can be shaken up conveniently.

Preferably, the material storage branched chain comprises a sliding bottom plate, an electric heating bottom plate, a connecting bottom frame and a demoulding cylinder, the sliding bottom plate is arranged on the lower side wall in the supporting box in a front-back sliding fit mode, an electric heating net framework is arranged at the upper end of the sliding bottom plate, the electric heating bottom plate is arranged at the upper end of the sliding bottom plate, positioned on the inner side of the electric heating net framework, in an up-down sliding fit mode, the electric heating bottom plate is connected through the connecting bottom frame, the demoulding cylinder is arranged at the lower end of the connecting bottom frame, and the demoulding cylinder is connected with the sliding bottom plate in a front-back sliding fit mode; through adopting above-mentioned technical scheme, can carry out the bearing to the raw materials and cut off to can also carry out drawing of patterns to the building block after accomplishing the solidification and handle.

Preferably, the scraping branch chain comprises a strip-shaped plate, an electric slide bar, an electric slide block, a scraping inclined plate and a herringbone guide plate, the strip-shaped plate is symmetrically arranged at the front and back of the upper end of the bearing box, a slide bar groove is formed in the side face of the strip-shaped plate opposite to the side face, the electric slide bar is arranged between the left side wall and the right side wall of the slide bar groove, the electric slide block is arranged on the electric slide bar in a left-right sliding fit mode, the upper ends of the electric slide blocks at the front side and the back side are connected through the scraping inclined plate, the upper end of the left side of the bearing box is obliquely arranged, and the herringbone guide plate is arranged at the upper side of the driven rotating rod in the middle of the left side of the bearing box; through adopting above-mentioned technical scheme, can strike off the raw materials upper end after aerifing to can avoid the not smooth problem in surface of building block enough.

Preferably, the transmission mechanism comprises a transmission supporting plate, a transmission roller and a transmission belt, a second motor, a motor plate, a third screw rod and a third motor, wherein transmission supporting plates are arranged between the supporting side plates in a vertically sliding fit mode, transmission grooves are symmetrically formed in the front side and the rear side of each transmission supporting plate, transmission rollers are arranged between the left side wall and the right side wall of each transmission groove in a rotationally fit mode, the transmission rollers are connected through transmission belts, the right end of each transmission roller on the front side penetrates through the transmission supporting plates and is connected with an output shaft of the second motor, the second motor passes through a motor base and is connected with the transmission supporting plates, the motor plate is arranged on the supporting side plate on the front side of the right end, the third screw rod is arranged between the motor plate and the base in a rotationally fit mode, the third screw rod is in threaded fit with the transmission supporting plates, the upper end of the third screw rod penetrates through the motor plate and is connected with output shafts of the third motor, and the third motor is installed on the motor plate through the motor base; through adopting above-mentioned technical scheme, can accept the building block after the drawing of patterns to with the building block to one side transmission.

In addition, the invention also provides a method for processing the building heat-insulation building block, which comprises the following steps of S1: adding the heat-preservation building block raw material which is subjected to blending and stirring into the die mechanism, heating the raw material through the die mechanism to enable the contact part of the raw material and the die mechanism to be solidified, connecting the inflating mechanism with an external inert gas inflating machine, and inflating the raw material through the inflating mechanism.

S2: after the raw materials are inflated, the raw materials are upwards separated from the die mechanism through the inflating mechanism, then the upper ends of the raw materials are heated and solidified through the cover plate mechanism, and after the raw materials are solidified into building blocks, the cover plate mechanism is upwards reset.

S3: the mold mechanism drives the building blocks to rotate by one hundred eighty degrees, and then drives the transmission mechanism to move upwards to the lower side of the mold mechanism, so that the building blocks can fall downwards to the upper end of the transmission mechanism, then the transmission mechanism is driven to reset downwards, the building blocks at the upper end of the transmission mechanism are transmitted to one side, and finally the building blocks are taken out and carried out.

In summary, the present application includes at least one of the following beneficial technical effects:

according to the invention, the interior of the raw material can be inflated through the inflating mechanism, so that the size of a gap in the aerated building block is increased, the using amount of the raw material is reduced, the production cost of the aerated building block is reduced, and the sound insulation and heat insulation performance of the aerated building block is improved.

The aerated building block can be produced under the condition that the aerated building block is not required to be cut through the die mechanism, so that the steps of producing the aerated building block are reduced, and the purchase, use and maintenance costs required when the aerated building block is cut are reduced.

Drawings

The invention is further illustrated with reference to the following figures and examples.

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

FIG. 2 is a schematic view of the structure between the base, the supporting side plates and the mold mechanism of the present invention.

FIG. 3 is a schematic view of the structure between the base, the support side plates and a portion of the mold mechanism of the present invention.

FIG. 4 is a schematic view of the structure between the holding box and the material-holding branch chain of the present invention.

FIG. 5 is a schematic view of the partial structure between the base, the supporting side plates and the mold mechanism of the present invention.

Fig. 6 is a schematic structural view among the fixed block, the driven rotating rod and the turning branched chain according to the present invention.

FIG. 7 is a schematic view of the structure between the support side panels, the support top panel and the inflation mechanism of the present invention.

Fig. 8 is a schematic view of the structure between the supporting side plate, the supporting top plate and the cover plate mechanism according to the present invention.

Fig. 9 is a schematic structural view among the base, the supporting side plates and the transfer mechanism of the present invention.

In the figure, 1, a base; 2. supporting the side plates; 3. supporting a top plate; 4. an inflation mechanism; 5. a cover plate mechanism; 6. a mold mechanism; 7. a transport mechanism; 41. a lifting cylinder; 42. mounting a plate; 43. adjusting the branched chain; 44. a hollow exhaust plate; 45. A connecting cylinder; 46. a balance plate; 47. an exhaust funnel; 48. a one-way valve; 431. a lifting rack; 432. a gear lever; 433. A transmission gear; 434. a rotating electric machine; 435. a limiting cylinder; 436. a limiting clamping block; 51. a driven plate; 52. a first lead screw; 53. rotating the motor; 54. \ 21274and a shaped connecting plate; 55. a top cover upper plate; 56. an electric hot plate; 57. a material blocking upper plate; 58. A push-pull cylinder; 61. a fixed block; 62. a driven rotating rod; 63. turning over the branched chain; 64. a supporting box; 65. a reciprocating branched chain; 66. a material storage branched chain; 67. scraping a branched chain; 631. a rotating gear; 632. a driving cylinder; 633. a driven rack; 651. Connecting the rotating rod; 652. an elliptical block; 653. a first motor; 654. a reset pressure spring rod; 661. a sliding bottom plate; 662. an electric heating grid frame; 663. an electric heating soleplate; 664. connecting the underframe; 665. a demoulding cylinder; 671. a strip plate; 672. an electric slide bar; 673. an electric slider; 674. a scraping inclined plate; 675. a herringbone guide plate; 71. conveying the supporting plate; 72. a driving roller; 73. a conveyor belt; 74. a second motor; 75. a motor plate; 76. a third screw rod; 77. and a third motor.

Detailed Description

Embodiments of the invention will be described in detail below with reference to the accompanying fig. 1-9, but the invention can be implemented in many different ways, which are defined and covered by the claims.

The embodiment of the application discloses insulation block processing system and method for building engineering construction, the description has, this building insulation block processing system and method is mainly used in the process of producing insulation blocks, can carry out inert gas's filling to polylith building block inside simultaneously in the technical effect under the condition that need not cut the building block, especially before aerifing, can heat the surface of raw materials earlier thereby the solidification of raw materials is accelerated, just then aerify it, thereby avoid inert gas to leak, and can also carry out the inflation of multiple-point type layering to the raw materials, make aerify more even, and reduced the use amount to the raw materials, the heat preservation effect of cutting the piece has been increased, later can also drive the building block after aerifing to shake and rock, thereby increase the even degree of inert gas in the building block.

The first embodiment is as follows:

referring to fig. 1, insulation block system of processing for building engineering construction, including base 1, and the left and right sides of setting in base 1 upper end and be the support curb plate 2 of front and back symmetric distribution, and the support roof 3 of setting between 2 upper ends of support curb plate, it is used for carrying out the mechanism of aerifing 4 to insulation block to have set up on the support roof 3, the mechanism of aerifing 4 downside has set up the apron mechanism 5 that is used for sheltering from insulation block's upper end, it has set up the mould mechanism 6 that is used for bearing insulation block raw materials to lie in 5 downside of apron mechanism between the support curb plate 2, it sets up the transmission device 7 that is used for accepting insulation block to lie in 6 downside of mould mechanism between the support curb plate 2.

At first, heat preservation building block raw materials after the allotment stirring are carried out the bearing through mould mechanism 6, then aerify the raw materials through aerifing mechanism 4, the raw materials upper end after rethread apron mechanism 5 will aerify covers, after the raw materials solidifies into the building block, mould mechanism 6 can overturn, transport mechanism 7 can upwards accept the building block, later transport mechanism 7 will reset to the downside and with the building block to one side transmission to the completion is to heat preservation building block's production.

Referring to fig. 2, which is the mold mechanism 6 in the present application, specifically, the mold mechanism 6 includes a fixed block 61, a driven rotating rod 62, and an overturning branch 63, bearing box 64, reciprocal branch chain 65, material stock branch chain 66 and scrape material branch chain 67, all be provided with fixed block 61 between the front and back both sides support curb plate 2, fixed block 61 middle part all is provided with driven bull stick 62 through normal running fit's mode, the right-hand member of the driven bull stick 62 on right side is provided with upset branch chain 63, upset branch chain 63 can drive driven bull stick 62 and overturn, the opposite side of the driven bull stick 62 of the left and right sides is connected through bearing box 64, be provided with reciprocal branch chain 65 on bearing box 64's the lateral wall, the inside material stock branch chain 66 that is provided with of bearing box 64, reciprocal branch chain 65 can drive material stock branch chain 66 and carry out reciprocating motion, bearing box 64 upper end is provided with scrapes material branch chain 67, material branch chain 67 can be scraped material stock branch chain 66 upper end.

During operation, at first place the raw materials in stock branch 66, the part that its and raw materials contacted heats through stock branch 66 to make the border of raw materials solidify earlier, later insert the inside downside of raw materials through inflating mechanism 4 again, 4 intermittent type nature upward movements of inflating mechanism, intermittent type nature fills inert gas in this in-process toward the raw materials, after the completion aerifys the raw materials, rethread inflating mechanism 4 upward movement resets, then strickles the raw materials upper end through scraping material branch 67, rethread apron mechanism 5 pressfitting is in the raw materials upper end and heats the raw materials downwards.

After the surface of raw materials has all solidified, drive material stock branch 66 and building block through reciprocal branch chain 65 and carry out reciprocating shaking all around, make the inside inert gas of building block can be rocked evenly, after the building block solidifies completely, reset through apron mechanism 5 rebound, rethread upset branch chain 63 drives bearing box 64 and carries out one hundred eighty degrees rotations, later through transmission device 7 rebound to the building block downside, rethread material stock branch chain 66 carries out the drawing of patterns to the building block and handles, make the building block can drop to transmission device 7 upper end downwards.

Referring to fig. 3 and 4, namely, the material storage branched chain 66 is used for supporting the mixed and stirred raw materials at intervals, specifically, the material storage branched chain 66 comprises a sliding bottom plate 661, an electric heating net framework 662, an electric heating bottom plate 663, a connecting bottom frame 664 and a demoulding cylinder 665, the sliding bottom plate 661 is arranged on the inner lower side wall of the bearing box 64 in a front-back sliding fit manner, an electric heating grid framework 662 is arranged at the upper end of the sliding bottom plate 661, the electric heating bottom plate 663 is arranged on the inner side of the electric heating net framework 662 at the upper end of the sliding bottom plate 661 in an up-down sliding fit manner, the electric heating net framework 662 can space the raw materials, and therefore the subsequent cutting process of the building blocks is reduced.

Electric heat net rack 662 can also heat the raw materials that lie in its inboard, electric heat bottom plate 663 can heat the downside of raw materials simultaneously, thereby play the effect of solidifying earlier of the border part of raw materials with higher speed, electric heat bottom plate 663 is connected through connecting chassis 664, it is provided with drawing of patterns cylinder 665 to connect chassis 664 lower extreme, drawing of patterns cylinder 665 is connected with sliding bottom plate 661 through front and back sliding fit, when needing to carry out the drawing of patterns to the building block that solidifies completely, drawing of patterns cylinder 665 can drive electric heat bottom plate 663 through connecting chassis 664 and remove, can push the building block after the upset downwards when electric heat bottom plate 663 removes, the building block can be pushed to breaking away from electric heat net rack 662.

Example two:

referring to fig. 5, on the basis of the first embodiment, in order to avoid that the upper end of the raw material inserted and pulled by the inflating mechanism 4 is not flat enough, a scraping branch chain 67 for scraping the upper end of the raw material is arranged at the upper end of the bearing box 64, specifically, the scraping branch chain 67 comprises a strip-shaped plate 671, an electric slide bar 672, an electric slide block 673, a scraping inclined plate 674 and a herringbone guide plate 675, the strip-shaped plate 671 is symmetrically arranged at the upper end of the bearing box 64 in the front-back direction, slide bar grooves are formed in the opposite side surfaces of the strip-shaped plate 671, the electric slide bar 672 is arranged between the left side wall and the right side wall of each slide bar groove, the electric slide bar 672 is provided with an electric slide block 673 in a left-right sliding fit manner, and the upper ends of the electric slide blocks 673 at the front side and the rear side are connected through the scraping inclined plate 674.

Can drive when electronic slider 673 removes and scrape material swash plate 674 and remove, can strike off the upper end of raw materials when scraping material swash plate 674 and removing, bearing case 64 left side upper end sets up for the slope, and bearing case 64 left side middle part is located driven bull stick 62 upside and is provided with herringbone guide plate 675, scrape when moving to the left side by scraping material swash plate 674 when the raw materials, the left slope department of bearing case 64 is convenient for the raw materials and is slided downwards, herringbone guide plate 675 can protect driven bull stick 62 upper end, avoid the raw materials to cause the influence to driven bull stick 62.

Continuing to refer to fig. 5, in order to make the inert gas inside the raw material distributed more uniformly, a reciprocating branched chain 65 is provided for driving the material storage branched chain 66 and the raw material inside the material storage branched chain to reciprocate back and forth, specifically, the reciprocating branched chain 65 includes a connecting rotating rod 651, an elliptical block 652, a first motor 653 and a reset pressure spring rod 654, a rotating through groove is uniformly provided on the front side surface of the bearing box 64, the middle part of the rotating through groove is connected in a rotating fit manner through the connecting rotating rod 651, the elliptical block 652 is provided in the rotating through groove on the outer side surface of the connecting rotating rod 651, the outer side surface of the elliptical block 652 is attached to the electric heating net grillage 662, the motor groove is provided at the right end of the connecting rotating rod 651 of the bearing box 64, and the first motor 653 is provided in the motor groove through the motor base.

The output shaft of the first motor 653 is connected with the connecting rotary rod 651, the back side wall of the bearing box 64 is provided with a reset pressure spring rod 654, and the front end of the reset pressure spring rod 654 is connected with an electric heating net grillwork 662. When the output shaft of the first motor 653 rotates, the connecting rotary rod 651 drives the elliptical block 652 to rotate, when the elliptical block 652 rotates, the elastic force of the reset pressure spring rod 654 drives the electric heating grid frame 662, the electric heating bottom plate 663, the connecting bottom frame 664 and the demoulding cylinder 665 to reciprocate back and forth, and when the electric heating grid frame 662 and the electric heating bottom plate 663 reciprocate back and forth, inert gas in raw materials can shake more uniformly, so that the effect of charging the raw materials is improved.

Referring to fig. 6, in order to facilitate carrying out more efficient demoulding treatment on the solidified heat-insulating building block, an overturning branch chain 63 is provided, specifically, the overturning branch chain 63 comprises a rotating gear 631, a driving cylinder 632 and a driven rack 633, the right end of a driven rotating rod 62 on the right side penetrates through a fixed block 61 and is provided with the rotating gear 631, the lower side of the fixed block 61 on the right side is provided with the driving cylinder 632 through a cylinder seat, the upper end of the driving cylinder 632 is provided with the driven rack 633 meshed with the rotating gear 631, when the bearing box 64 needs to be driven to overturn, the driving cylinder 632 can drive the driven rack 633 to move, the driven rotating rod 62 and the bearing box 64 can be driven to overturn by one hundred eighty degrees through the rotating gear 631 when the driven rack 633 moves, and demoulding on the building block can be facilitated by overturning the bearing box 64.

Example three:

referring to fig. 7, on the basis of the second embodiment, in order to fill the inert gas into different positions in the raw material more uniformly, the gas filling mechanism 4 is provided, specifically, the gas filling mechanism 4 comprises a lifting cylinder 41, a mounting plate 42, an adjusting branch chain 43 and a hollow exhaust plate 44, the gas-liquid separation device comprises a connecting cylinder 45, a balance plate 46, an exhaust cylinder 47 and a one-way valve 48, wherein a lifting cylinder 41 is arranged in the middle of a supporting top plate 3, the telescopic end of the lower side of the lifting cylinder 41 penetrates through the supporting top plate 3 and is provided with a mounting plate 42, the lifting cylinder 41 can drive the mounting plate 42 to move downwards or reset upwards, adjusting branched chains 43 are arranged on the front side and the rear side of the mounting plate 42, a hollow exhaust plate 44 is installed at the lower end of the adjusting branched chain 43, the adjusting branched chain 43 can indirectly drive the hollow exhaust plate 44 to move upwards in an intermittent manner, the connecting cylinder 45 is arranged at the upper end of the hollow exhaust plate 44, and the connecting cylinder 45 can be connected with an external inert gas inflation machine.

The left side and the right side of the hollow exhaust plate 44 are provided with balance plates 46 which are in up-and-down sliding fit with the supporting side plates 2, the balance plates 46 can keep the stability degree of the hollow exhaust plate 44 when moving up and down, the lower end of the hollow exhaust plate 44 is uniformly provided with exhaust cylinders 47 which are communicated with the lower end of the hollow exhaust plate 44, the lower ends of the exhaust cylinders 47 are provided with one-way valves 48, the one-way valves 48 can prevent raw materials from entering the exhaust cylinders 47 in the process that the exhaust cylinders 47 insert the raw materials, when the raw materials need to be inflated, an external inert gas inflation machine can inflate the hollow exhaust plate 44 and the exhaust cylinders 47 through the connecting cylinders 45, inert gas can enter the raw materials along the exhaust cylinders 47, in the process, the adjusting branched chains 43 can indirectly drive the hollow exhaust plate 44 and the exhaust cylinders 47 to move upwards, and therefore different positions in the raw materials can be inflated through the plurality of exhaust cylinders 47.

With continued reference to fig. 7, to enable the chimney 47 to be inflated at various locations within the feedstock, the adjusting branched chain 43 is arranged on the mounting plate 42, specifically, the adjusting branched chain 43 comprises a lifting rack 431, a gear rod 432, a transmission gear 433, a rotating motor 434, a limiting cylinder 435 and a limiting fixture block 436, the lifting rack 431 is symmetrically arranged on the mounting plate 42 in a vertical sliding fit manner, the lower end of the lifting rack 431 is connected with the hollow exhaust plate 44, a gear groove is formed in the mounting plate 42 on the opposite side of the lifting rack 431, the gear rod 432 is arranged in the gear groove in a rotating fit manner, the transmission gear 433 meshed with the lifting rack 431 is arranged on the outer side surface of the gear rod 432, the right end of the gear rod 432 penetrates through the mounting plate 42 and is connected with an output shaft of the rotating motor 434, and the rotating motor 434 is connected with the mounting plate 42 through a motor base.

The output shaft of the rotating motor 434 can rotate to drive the transmission gear 433 to rotate through the gear rod 432, when the transmission gear 433 rotates, the hollow exhaust plate 44 can be driven to move downwards or reset upwards through the lifting rack 431, thereby the exhaust pipe 47 can be driven to different positions, the front end and the rear end of the mounting plate 42 are symmetrically provided with cylinder grooves, the cylinder groove is internally provided with a limit cylinder 435, the telescopic end at the opposite side of the limit cylinder 435 is provided with a limit fixture block 436 corresponding to the transmission gear 433, after the lifting rack 431 moves upwards once, the limiting cylinder 435 can drive the limiting fixture block 436 to move towards the side close to the transmission gear 433, so that the limit fixture block 436 can fix the transmission gear 433, the exhaust pipe 47 exhausts the gas to the interior of the raw material when the transmission gear 433 is fixed, when the transmission gear 433 needs to rotate, the limiting cylinder 435 can drive the limiting fixture block 436 to move towards the side far away from the transmission gear 433.

Example four:

referring to fig. 8, on the basis of the third embodiment, in order to cover the upper end of the raw material in the electric heating grid frame 662, a cover plate mechanism 5 is provided, specifically, the cover plate mechanism 5 includes a driven plate 51, a first lead screw 52, a rotating motor 53, a 21274, a connecting plate 54, a top cover upper plate 55, an electric heating plate 56, a material blocking upper plate 57 and a push-pull cylinder 58, the driven plate 51 is provided between the front and rear side support side plates 2 in a vertical sliding fit manner, the first lead screw 52 is provided in the middle of the left driven plate 51 in a threaded fit manner, the upper end of the first lead screw 52 penetrates through the support top plate 3 and is connected with the output shaft of the rotating motor 53, the rotating motor 53 is installed at the upper end of the support top plate 3 through a motor base, the output shaft of the rotating motor 53 can drive the first lead screw 52 to rotate, the first lead screw 52 can drive the driven plate 51 to move upwards or downwards when rotating, the support side plate 2 can be restrained and guided as the driven plate 51 moves.

The opposite sides of the left driven plate 51 and the right driven plate 51 are respectively provided with a v-21274a-shaped connecting plate 54 and a v-21274a-shaped connecting plate 54, the v-21274a-shaped connecting plates 54 are connected through a top cover upper plate 55, the lower side surface of the top cover upper plate 55 is provided with an electric heating plate 56, the electric heating plate 56 can heat the upper end of the raw material so as to accelerate the solidification of the raw material, when the lifting cylinder 41 indirectly drives the exhaust funnel 47 to move downwards, the rotating motor 53 indirectly drives the electric heating plate 56 to move downwards so as to avoid blocking the hollow exhaust panel 44, a through rod through hole corresponding to the exhaust funnel 47 is respectively arranged between the top cover upper plate 55 and the electric heating plate 56, the exhaust funnel 47 can pass downwards through the through rod through hole, a baffle groove is arranged in the top cover upper plate 55, the baffle groove is provided with an upper plate 57 in a sliding fit manner, a circular through hole corresponding to the through rod through hole is also arranged on the baffle upper plate 57, when the circular through hole corresponds to the through hole, the exhaust pipe 47 can penetrate downwards, one side of the upper baffle plate 57 is connected with the side wall of the baffle groove through the push-pull cylinder 58, and when the exhaust pipe 47 is separated from the electric heating plate 56 upwards, the push-pull cylinder 58 can drive the upper baffle plate 57 to move, so that the upper baffle plate 57 can plug the rod penetrating through hole.

Referring to fig. 9, in order to receive and convey the blocks, a conveying mechanism 7 is provided at the lower side of the mold mechanism 6, and specifically, the conveying mechanism 7 includes a conveying pallet 71, a driving roller 72, a conveying belt 73, the second motor 74, the motor plate 75, the third screw 76 and the third motor 77, the transmission supporting plate 71 is arranged between the supporting side plates 2 in an up-down sliding fit mode, transmission grooves are symmetrically formed in the front side and the rear side of the transmission supporting plate 71, the transmission rollers 72 are arranged between the left side wall and the right side wall of each transmission groove in a rotating fit mode, the transmission rollers 72 are connected through the transmission belt 73, the right end of the transmission roller 72 on the front side penetrates through the transmission supporting plate 71 and is connected with the output shaft of the second motor 74, the second motor 74 is connected with the transmission supporting plate 71 through a motor base, the output shaft of the second motor 74 can drive the transmission rollers 72 and the transmission belt 73 to rotate, and the transmission belt 73 can transmit the building blocks to one side.

Be provided with motor board 75 on the support curb plate 2 of right-hand member front side, be provided with three lead screw 76 through normal running fit's mode between motor board 75 and the base 1, three lead screw 76 and transmission layer board 71 screw-thread fit, three 76 upper ends of lead screw pass motor board 75 and be connected with three 77 output shafts of motor, three 77 of motor pass through the motor cabinet and install on motor board 75, three 77 output shafts of motor are rotatory to drive three 76 of lead screw and rotate, can drive transmission layer board 71 rebound and accept the building block when three 76 of lead screw rotate, can also drive transmission layer board 71 rebound to the base 1 upper end, later the rethread transmission band 73 with the building block to one side transmission.

In addition, the invention also provides a method for processing the building heat-insulation building block, which comprises the following steps: s1: adding the heat-preservation building block raw material which is subjected to mixing and stirring into the die mechanism 6, heating the raw material through the die mechanism 6 to enable the contact part of the raw material and the die mechanism 6 to be solidified, connecting the inflating mechanism 4 with an external inert gas inflating machine, and inflating the raw material through the inflating mechanism 4.

S2: after the raw materials are inflated, the raw materials are upwards separated from the die mechanism 6 through the inflating mechanism 4, then the upper ends of the raw materials are heated and solidified through the cover plate mechanism 5, and after the raw materials are solidified into building blocks, the cover plate mechanism 5 is upwards reset.

S3: the mould mechanism 6 drives the building blocks to rotate by one hundred eighty degrees, and then the transmission mechanism 7 is driven to move upwards to the lower side of the mould mechanism 6, so that the building blocks can fall downwards to the upper end of the transmission mechanism 7, then the transmission mechanism 7 is driven to reset downwards, and the building blocks at the upper end of the transmission mechanism are transmitted to one side.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The utility model provides a thermal insulation block system of processing for building engineering construction, includes base (1) and sets up the left and right sides in base (1) upper end and support curb plate (2) that are front and back symmetric distribution to and set up supporting roof (3) between supporting curb plate (2) upper end, its characterized in that: supporting roof (3) is last to be provided with and to be used for carrying out the aerated mechanism (4) of aerifing to insulation block, and mechanism (4) downside of aerifing has set up apron mechanism (5) that are used for sheltering from insulation block's upper end, and it has set up mould mechanism (6) that are used for bearing insulation block raw materials to lie in apron mechanism (5) downside between support curb plate (2), and it has set up transmission device (7) that are used for accepting insulation block to lie in mould mechanism (6) downside between support curb plate (2), wherein:

the inflation mechanism (4) comprises a lifting cylinder (41) arranged at the lower end of the middle part of the supporting top plate (3) and a mounting plate (42) arranged at the lower end of the lifting cylinder (41), wherein adjusting branched chains (43) used for adjusting up and down are arranged at the front end and the rear end of the mounting plate (42), a hollow exhaust plate (44) adjusted by the adjusting branched chains is arranged at the lower end of the adjusting branched chains (43), a connecting cylinder (45) used for being communicated with an air pump is arranged on the hollow exhaust plate (44), exhaust cylinders (47) communicated with the hollow exhaust plate and used for inflating the heat-insulating building blocks are uniformly arranged at the lower end of the hollow exhaust plate (44), and one-way valves (48) for preventing raw materials from entering the exhaust cylinders (47) are arranged at the lower ends of the exhaust cylinders (47);

the die mechanism (6) comprises a bearing box (64) which is arranged between the supporting side plates (2) and used for bearing and containing the heat-insulating block raw materials, and an electric heating grid frame (662) which is arranged in the bearing box (64) and used for spacing the heat-insulating block raw materials to form a block shape.

2. The heat-insulating block processing system for construction of building engineering according to claim 1, characterized in that: the adjusting branched chain (43) comprises a lifting rack (431), a gear rod (432), a transmission gear (433), a rotating motor (434), a limiting cylinder (435) and a limiting fixture block (436), wherein the lifting rack (431) is symmetrically arranged on the mounting plate (42) in a vertical sliding fit manner, the lower end of the lifting rack (431) is connected with the hollow exhaust plate (44), a gear groove is formed in the mounting plate (42) and is opposite to the lifting rack (431), the gear rod (432) is arranged in the gear groove in a rotating fit manner, the transmission gear (433) meshed with the lifting rack (431) is arranged on the outer side surface of the gear rod (432), the right end of the gear rod (432) penetrates through the mounting plate (42) and is connected with an output shaft of the rotating motor (434), the rotating motor (434) is connected with the mounting plate (42) through a motor base, the cylinder grooves are symmetrically formed in the front end and the rear end of the mounting plate (42), a limiting cylinder (435) is arranged in the cylinder groove, and a limiting fixture block (436) corresponding to the transmission gear (433) is arranged at the telescopic end of the opposite side of the limiting cylinder (435).

3. The heat insulation block processing system for constructional engineering construction according to claim 1, wherein: the cover plate mechanism (5) comprises driven plates (51), a first lead screw (52), a rotating motor (53), an electrical heating plate (21274), a shape connecting plate (54), a top cover upper plate (55), an electric heating plate (56), a baffle upper plate (57) and a push-pull air cylinder (58), wherein the driven plates (51) are arranged between the supporting side plates (2) on the front side and the rear side in a vertical sliding fit mode, the first lead screw (52) is arranged in the middle of the left driven plate (51) in a threaded fit mode, the upper end of the first lead screw (52) penetrates through the supporting top plate (3) and is connected with an output shaft of the rotating motor (53), the rotating motor (53) is installed at the upper end of the supporting top plate (3) through a motor base, the electrical heating plate (56) is arranged on the lower side of the top cover upper plate (55) through the shape connecting plate (54) on the left side and the right side, the lower side of the driven plate (51), the through rod through holes corresponding to the exhaust pipes (47) are formed between the top cover upper plate (55) and the electric heating plate (56), the baffle grooves are formed in the top cover upper plate (55), the baffle plate upper plates (57) are arranged in the baffle grooves in a sliding fit mode, circular through holes corresponding to the through rod through holes are also formed in the baffle plate upper plates (57), and one side of each baffle plate upper plate (57) is connected with the side wall of each baffle groove through a push-pull cylinder (58).

4. The heat-insulating block processing system for construction of building engineering according to claim 1, characterized in that: the die mechanism (6) further comprises a fixing block (61), a driven rotating rod (62), an overturning branch chain (63), a reciprocating branch chain (65), a material storage branch chain (66) and a material scraping branch chain (67), wherein the fixing block (61) is arranged between the front side support side plate and the rear side support side plate (2), the driven rotating rod (62) is arranged in the middle of the fixing block (61) in a rotating fit mode, the overturning branch chain (63) is arranged at the right end of the driven rotating rod (62) on the right side, the opposite sides of the driven rotating rods (62) on the left side and the right side are connected through a bearing box (64), the reciprocating branch chain (65) is arranged on the side wall of the bearing box (64), the material storage branch chain (66) is arranged inside the bearing box (64), and the material scraping branch chain (67) is arranged at the upper end of the bearing box (64).

5. The insulation block processing system for construction of building engineering according to claim 4, wherein: the overturning branch chain (63) comprises a rotating gear (631), a driving cylinder (632) and a driven rack (633), the right end of the driven rotating rod (62) on the right side penetrates through the fixed block (61) and is provided with the rotating gear (631), the lower side of the fixed block (61) on the right side is provided with the driving cylinder (632) through a cylinder seat, and the driven rack (633) meshed with the rotating gear (631) is arranged at the upper end of the driving cylinder (632).

6. The heat insulation block processing system for constructional engineering construction according to claim 4, wherein: the reciprocating branched chain (65) comprises a connecting rotating rod (651), an oval block (652), a motor I (653) and a reset pressure spring rod (654), a rotating through groove is uniformly formed in the front side face of the bearing box (64), the middle of the rotating through groove is connected in a rotating fit mode through the connecting rotating rod (651), the oval block (652) is arranged in the rotating through groove on the outer side face of the connecting rotating rod (651), the outer side face of the oval block (652) is attached to the material storage branched chain (66), a motor groove is formed in the right end, located at the connecting rotating rod (651), of the bearing box (64), the motor I (653) is arranged in the motor groove through a motor base, the output shaft of the motor I (653) is connected with the connecting rotating rod (651), the reset pressure spring rod (654) is arranged on the rear side wall of the bearing box (64), and the front end of the reset pressure spring rod (654) is connected with the material storage branched chain (66).

7. The insulation block processing system for construction of building engineering according to claim 4, wherein: the material storage branched chain (66) comprises a sliding bottom plate (661), an electric heating bottom plate (663), a connecting bottom frame (664) and a demolding cylinder (665), wherein the sliding bottom plate (661) is arranged on the inner lower side wall of the bearing box (64) in a front-back sliding fit mode, an electric heating grid frame (662) is arranged at the upper end of the sliding bottom plate (661), the electric heating bottom plate (663) is arranged on the inner side of the electric heating grid frame (662) at the upper end of the sliding bottom plate (661), the electric heating bottom plate (663) is connected through the connecting bottom frame (664), the demolding cylinder (665) is arranged at the lower end of the connecting bottom frame (664), and the demolding cylinder (665) is connected with the sliding bottom plate (661) in a front-back sliding fit mode.

8. The insulation block processing system for construction of building engineering according to claim 4, wherein: scraping branch chain (67) include strip shaped plate (671), electric slide bar (672), electronic slider (673), scrape material swash plate (674) and herringbone baffle (675), bearing case (64) upper end front and back symmetry is provided with strip shaped plate (671), the slide bar groove has been seted up on the carried back side face of strip shaped plate (671), be provided with electric slide bar (672) between the lateral wall about the slide bar groove, be provided with electric slider (673) through side-to-side sliding fit's mode on electric slide bar (672), electric slider (673) upper end of front and back both sides is connected through scraping material swash plate (674), bearing case (64) left side upper end sets up for the slope, and bearing case (64) left side middle part is located driven bull stick (62) upside and is provided with herringbone baffle (675).

9. The heat-insulating block processing system for construction of building engineering according to claim 1, characterized in that: the transmission mechanism (7) comprises a transmission supporting plate (71), transmission rollers (72), a transmission belt (73), a motor II (74), a motor plate (75), a screw rod III (76) and a motor III (77), the transmission supporting plate (71) is arranged between the supporting side plates (2) in an up-down sliding fit mode, transmission grooves are symmetrically formed in the front side and the rear side of the transmission supporting plate (71), the transmission rollers (72) are arranged between the left side wall and the right side wall of each transmission groove in a rotating fit mode, the transmission rollers (72) are connected with each other through the transmission belt (73), the right end of the transmission roller (72) in the front side penetrates through the transmission supporting plate (71) and is connected with an output shaft of the motor II (74), the motor II (74) is connected with the transmission supporting plate (71) through a motor base, the motor plate (75) is arranged on the supporting side plate (2) in the front side of the right end, the screw rod III (76) is arranged between the motor plate (75) and the base (1) in a rotating fit mode, the third screw rod (76) is in threaded fit with the transmission supporting plate (71), the upper end of the third screw rod (76) penetrates through the motor plate (75) and is connected with an output shaft of the third motor (77), and the third motor (77) is installed on the motor plate (75) through the motor base.

10. The insulation block processing system for building engineering construction according to claim 1, wherein the insulation block processing system for building engineering construction comprises the following steps:

s1: adding the prepared and stirred raw materials of the heat-preservation building blocks into the die mechanism (6), heating the raw materials through the die mechanism (6) to enable the contact part of the raw materials and the die mechanism (6) to be solidified, communicating the inflating mechanism (4) with an external inert gas inflating machine, and inflating the raw materials through the inflating mechanism (4);

s2: after the raw materials are aerated, the raw materials are upwards separated from the die mechanism (6) through the aerating mechanism (4), then the upper ends of the raw materials are heated and solidified through the cover plate mechanism (5), and after the raw materials are solidified into building blocks, the cover plate mechanism (5) is upwards reset;

s3: the mould mechanism (6) drives the building blocks to rotate by one hundred eighty degrees, and then the transmission mechanism (7) is driven to move upwards to the lower side of the mould mechanism (6), so that the building blocks can fall downwards to the upper end of the transmission mechanism (7), then the transmission mechanism (7) is driven to reset downwards, and the building blocks at the upper end of the transmission mechanism are transmitted to one side.

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