CN115847606A

CN115847606A - Thermal insulation mortar processing method

Info

Publication number: CN115847606A
Application number: CN202211583302.7A
Authority: CN
Inventors: 陈常
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-12-09
Filing date: 2022-12-09
Publication date: 2023-03-28

Abstract

The invention relates to the field of building construction, in particular to a method for processing thermal insulation mortar, which comprises the following steps: the mortar after mixing and proportioning is put into a separation stirring box for mixing and stirring, and the stirred mortar is separated in equal proportion by driving a separation adding table; the separating adding table corresponds to a transversely sliding disassembling transverse sliding table; driving the dismounting transverse sliding table to separate the mortar from falling through the separating and adding table; adding liquid heat-insulating rubber into the separated mortar through the extrusion pipe by driving extrusion; extruding out partial mortar by extrusion to ensure that rubber is uniformly and quantitatively arranged on the separated mortar; the partition table is disassembled in a sliding way to take out the mortar partitioned in equal proportion; taking out a batch of quantitative mortar with rubber for bonding construction; the invention has the beneficial effect that the thermal insulation mortar with the rubber separation layer inside is processed quantitatively in batches by the separation mortar for bonding in building.

Description

Thermal insulation mortar processing method

Technical Field

The invention relates to the field of building construction, in particular to a method for processing thermal insulation mortar.

Background

The mortar is bonded and isolated by spreading, so that the construction and effective isolation are facilitated, and the effect of effectively isolating temperature difference is generated; patent No. CN202111129372.0 discloses a method for processing thermal insulation mortar. The processing method comprises the following steps: s1: storing the vitrified micro bubbles by using a thermal insulation mortar processing device; s2: inserting the stored vitrified micro bubbles into the concrete for dispersion, and stirring the vitrified micro bubbles and the concrete together; s3: adding the heat-insulating glue powder and water into the concrete mixed with the vitrified micro bubbles; s4: fully stirring the vitrified micro bubbles, the concrete, the heat-insulating glue powder and the water together. Heat preservation mortar processingequipment includes square column, toper piece, a storage section of thick bamboo and well roof beam, and the lower extreme fixed connection of square column is all opened at the middle part of toper piece in the upper and lower both sides of a storage section of thick bamboo, and the roof beam in the upside fixedly connected with of a storage section of thick bamboo, the vertical sliding connection of square column are at the middle part of well roof beam, and the toper piece is located the downside of a storage section of thick bamboo. The upper half part and the lower half part of the conical block are both conical. However, the mortar processed by the processing method cannot be provided with rubber for barrier insulation.

Disclosure of Invention

The invention aims to provide a method for processing thermal insulation mortar, which has the beneficial effect that the thermal insulation mortar with a rubber separation layer inside is processed quantitatively in batches by the separation mortar for bonding in the building.

The purpose of the invention is realized by the following technical scheme: a method for processing thermal insulation mortar comprises the following steps:

step one, the mortar after mixing and proportioning is mixed and stirred in a separation stirring box, and the stirred mortar is separated in equal proportion by driving a separation adding table;

secondly, the separate adding table corresponds to a transversely sliding disassembling transverse sliding table; driving the dismounting transverse sliding table to separate the mortar from falling through the separating and adding table;

adding liquid heat-insulating rubber into the separated mortar through a driving extrusion pipe;

extruding out partial mortar by extrusion to uniformly and quantitatively arrange rubber on the separated mortar;

fifthly, sliding the disassembly separation table to take out the mortar which is separated in equal proportion; and taking out a batch of quantitative mortar with rubber for bonding construction.

The disassembly separation platform is internally provided with a closed disassembly bottom plate frame through sealing and disassembling of a sealing ring, a # -shaped separation frame used for separating quantitative mortar is fixed on the closed disassembly bottom plate, and a plurality of internal disassembly bottom plates are arranged in the # -shaped separation frame through sealing and disassembling of the sealing ring.

A disassembly combination rack for driving is fixed at the side end of the disassembly separation table, and a hand pull ring convenient to take out is fixed at the lower end of the disassembly separation table; the two ends of the disassembly separation table slide in the disassembly transverse sliding table through the limiting sliding blocks.

The disassembly transverse sliding table is meshed with and drives a transverse driver through a gear and a rack, the transverse driver is fixed on the fixed bottom table, and the disassembly transverse sliding table transversely slides in the fixed bottom table through a sliding block.

The mortar is prepared by respectively adding mixed mortar raw materials into a separation stirring box according to a ratio for mixing and stirring, inserting a separation adding table into the separation stirring box downwards through driving after stirring is completed, uniformly separating the mortar, transversely sliding a driving dismounting transverse sliding table to the lower end of the separation stirring box and corresponding to the separation of the separation adding table, quantitatively adding liquid heat-insulating rubber in the separation adding table into the separated mortar through driving extrusion after position determination, transversely sliding the driving dismounting transverse sliding table after rubber addition is completed, taking out quantitative mortar and middle quantitative rubber, bonding the rubber in the mortar, manually taking out mortar with rubber in batches, and further applying the mortar with rubber bonding to building construction to increase the bonding degree and increase the heat-insulating performance, thereby facilitating quantitative batch use on the building construction.

Drawings

FIG. 1 is a schematic flow chart of the preparation of the thermal mortar of the present invention;

FIG. 2 is a schematic structural view of a closed and disassembled floor frame of the present invention;

FIG. 3 is a first schematic view of the structure of the detaching table according to the present invention;

FIG. 4 is a second schematic structural view of the detachable partition table of the present invention;

FIG. 5 is a schematic view of the structure of the disassembled lateral sliding table of the present invention;

FIG. 6 is a schematic view of the structure of the fixed base table of the present invention;

FIG. 7 is a first schematic structural view of the partitioned agitator tank of the present invention;

FIG. 8 is a second schematic structural view of the partitioned agitator tank of the present invention;

FIG. 9 is a first schematic view of the structure of the separation adding station of the present invention;

FIG. 10 is a second schematic view of the structure of the separate adding station of the present invention;

FIG. 11 is a schematic view of the configuration of the extrusion column platform drive of the present invention;

FIG. 12 is a first overall schematic configuration of the present invention;

fig. 13 is a second overall configuration diagram of the present invention.

In the figure: the bottom plate frame 1 is closed and disassembled; a well-shaped separation frame 2; disassembling the separating table 3; the combined rack 4 is disassembled; an inner detachable bottom plate 5; a hand pull ring 6; the transverse sliding table 7 is disassembled; a transverse drive 8; a fixed base table 9; an upper longitudinal limit fixing frame 10; a partitioned agitator tank 11; an addition hopper 12; a stirring driver 13; a separate addition station 14; a longitudinal partition addition driver 15; a separation frame 16; an extruded tube 17; a squeeze screw driver 18; the ram platform 19 is squeezed.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in the embodiments illustrated herein,

Further optimization in conjunction with the above examples:

further, according to the working process of an example of the thermal mortar processing method shown in fig. 2, 3, 4 and 5, the working process is as follows:

dismantle the bottom plate frame 1 through the sealed seal of rubber circle in dismantling platform 3 and conveniently dismantle bottom plate frame 1 to the seal and be and carry the mortar use, dismantle the well word on the bottom plate frame 1 through the seal and separate frame 2 and conveniently with the partition of mortar ration batch, dismantle bottom plate 5 in the well word separates frame 2 through the sealed a plurality of interior dismantlement bottom plates of rubber circle and conveniently take out single interior dismantlement bottom plate 5 respectively after wholly taking out the seal dismantlement bottom plate frame 1, and then take out single mortar and carry out direct use.

Further optimization in conjunction with the above examples:

further, according to the working process of the example of the thermal mortar processing method shown in fig. 2, 3, 4 and 5, the working process is as follows:

the disassembly combination rack 4 for separating the side end of the platform 3 through disassembly is convenient to disassemble and assemble, the rack is prevented from being disconnected, the transverse driver 8 is convenient to combine and drive for transverse driving, the platform 3 is conveniently and transversely taken out through the hand pull ring 6 and is conveniently and transversely taken out to be slid and inserted in the disassembly separation platform 3 for disassembling the transverse sliding platform 7, and then the platform is conveniently taken out and switched for use.

Further optimization in conjunction with the above examples:

the dismounting transverse sliding table 7 is driven to transversely slide in the fixed bottom table 9 through the gear and rack meshing of the transverse driver 8, so that the dismounting transverse sliding table 7 can move conveniently to switch and block mortar to prevent leakage; the leakage prevention effect is realized by disassembling the closed barriers at the two ends of the transverse sliding table 7 in the process of taking out the mortar.

Further optimization in conjunction with the above examples:

further, a longitudinal limiting fixing frame 10 for limiting longitudinal limiting sliding is fixed at the upper end of the fixing base 9, and a separating stirring box 11 for stirring mortar is fixed in the longitudinal limiting fixing frame 10. The working process of the part according to the example of the thermal mortar processing method shown in the figures 6, 7, 8 and 9 is as follows:

fix through rag bolt with whole device through fixed base frame 9 and then, 11 are fixed to the rethread vertical spacing fixed frame 10 that will separate the agitator tank, separate 11 whole shapes of agitator tank and present type, make things convenient for the stirring to mix and do not influence the partition.

Further optimization in conjunction with the above examples:

further, two ends of the separation stirring box 11 are uniformly fixed and are communicated with a plurality of adding hoppers 12, a stirring driver 13 for stirring mortar is rotatably arranged in the separation stirring box 11, and a motor of the stirring driver 13 is fixed on the fixed base platform 9. The working process of the part according to the example of the thermal mortar processing method shown in the figures 6, 7, 8 and 9 is as follows:

through a plurality of interpolation fill 12 of separating 11 side end intercommunications and then conveniently add the mixed raw materials of mortar in equal proportion, and then through separating 13 drive stirring wings of 11 both ends internal rotations of agitator tank and rotate and realize stirring and mix, realize the drive that the stirring was mixed through the stirring wing that both sides set up, stirring driver 13 passes through synchronous belt drive synchronous drive stirring.

Further optimization in conjunction with the above examples:

furthermore, a separating and adding table 14 is arranged in the longitudinal limiting and fixing frame 10 in a longitudinal limiting and sliding manner, the separating and adding table 14 is connected with a longitudinal separating and adding driver 15 through threaded fit, and the longitudinal separating and adding driver 15 is fixed at the side end of the longitudinal limiting and fixing frame 10. The working process of the part according to the example of the thermal mortar processing method shown in the figures 9, 10, 11 and 12 is as follows:

the longitudinal separation adding driver 15 is fixed at the side end of the longitudinal limiting fixing frame 10 and drives the separation adding table 14 to longitudinally insert and slide in the longitudinal limiting fixing frame 10 through thread matching, so that longitudinal driving addition of the separation adding table 14 is realized, and separation of mixed and stirred mortar is realized through driving of the separation adding table 14.

Further optimization in conjunction with the above examples:

furthermore, a separation frame 16 is fixed at the lower end of the separation adding table 14, a plurality of extrusion pipes 17 are fixed in the separation frame 16, a rubber stock bin is arranged in the upper end of the separation adding table 14, and the extrusion pipes 17 are communicated with the rubber stock bin. The working process of the part according to the example of the thermal mortar processing method shown in the figures 9, 10, 11 and 12 is as follows:

the mortar is inserted into the mortar through the lower driving of the separation frame 16 and the plurality of extrusion pipes 17 which separate the lower end of the adding platform 14, the mortar is separated through the correspondence of the separation frame 16 and the # -shaped separation frame 2, and meanwhile, the rubber is conveniently added through the insertion of the plurality of extrusion pipes 17 into the mortar.

Further optimization in conjunction with the above examples:

furthermore, an extrusion thread driver 18 is fixed at the side end of the separation adding table 14, and the extrusion thread driver 18 drives an extrusion column platform 19 to longitudinally limit and slide on the separation adding table 14 through thread matching. A plurality of extrusion columns are fixed at the lower end of the extrusion column platform 19 and are inserted in the extrusion pipe 17; the working process of the part according to the example of the thermal insulation mortar processing method shown in fig. 10 and 11 is as follows:

through fixing 18 screw-thread fit drive extrusion column platforms 19 that add on separating platform 14 and adding platform 14 vertical spacing slip in separating, and then make extrusion column platform 19 push down the liquid rubber of storage in separating and adding 14 upper end rubber stock bins, and then the pressurization makes rubber pass through extrusion pipe 17 extrusion mortar, and then accomplish the ration of rubber and add, and then add quantitative rubber combination in making quantitative mortar, through rubber bonding in the mortar, make things convenient for the holistic bonding of mortar to use and then wrap up the building brick, it is isolated with the combination through rubber bonding simultaneously, accomplish the use of the mortar of an isolated cooling effect.

The fixed connection in the device can be fixed by welding, insert block combination and fixation, casting integral forming and fixation, thread fixation and the like, and the adaptive selection is carried out by combining the mounting and dismounting modes; the rotary connection can mean that the bearing is arranged on a shaft in a drying way, a spring retainer ring groove or an inter-shaft baffle is arranged on the shaft or a shaft hole, the axial fixation of the bearing is realized by clamping an elastic retainer ring in the spring retainer ring groove or the inter-shaft baffle, and the rotation is realized by the relative sliding of the bearing; the limit sliding is a sliding mode which limits the sliding track, the sliding direction and the position by the fit and matching sliding of a sliding block with a ball body or a bearing and the like for reducing the resistance and a sliding groove and limits the position by the limit; different connection modes are used for further distinguishing and using by combining different using environments.

Claims

1. A method for processing thermal insulation mortar is characterized by comprising the following steps: the method comprises the following steps:

step one, allowing the mixed and proportioned mortar to pass through a separation stirring box for mixing and stirring, and driving a separation adding table to separate the stirred mortar in equal proportion;

2. The thermal insulation mortar processing method according to claim 1, wherein a closed detachable bottom plate frame (1) is detachably arranged in the detachable separation platform (3) in a sealing manner through a sealing ring, a # -shaped separation frame (2) for separating quantitative mortar is fixed on the closed detachable bottom plate (1), and a plurality of inner detachable bottom plates (5) are detachably arranged in the # -shaped separation frame (2) in a sealing manner through a sealing ring.

3. The thermal insulation mortar processing method according to claim 2, wherein a disassembly combination rack (4) for driving is fixed at the side end of the disassembly separation table (3), and a hand pull ring (6) convenient to take out is fixed at the lower end of the disassembly separation table (3); two ends of the disassembly separation table (3) slide in the disassembly transverse sliding table (7) through limiting sliding blocks.

4. The thermal mortar processing method according to claim 1, wherein the detaching transverse sliding table (7) drives the transverse driver (8) through gear and rack meshing, the transverse driver (8) is fixed on the fixed base table (9), and the detaching transverse sliding table (7) slides transversely in the fixed base table (9) through a sliding block.

5. The method for processing the thermal mortar according to claim 4, wherein a longitudinal limit fixing frame (10) for limiting the longitudinal limit sliding is fixed at the upper end of the fixing base platform (9), and a separation stirring box (11) for stirring the mortar is fixed in the longitudinal limit fixing frame (10).

6. The thermal insulation mortar processing method according to claim 5, wherein a plurality of adding hoppers (12) are uniformly fixed and communicated at two ends of the separating and stirring tank (11), a stirring driver (13) for stirring mortar is rotatably arranged in the separating and stirring tank (11), and a motor of the stirring driver (13) is fixed on the fixed base (9).

7. The thermal insulation mortar processing method according to claim 5, wherein a separation adding table (14) is arranged in the longitudinal limiting fixing frame (10) in a longitudinal limiting sliding mode, the separation adding table (14) is connected with a longitudinal separation adding driver (15) through threaded fit, and the longitudinal separation adding driver (15) is fixed at the side end of the longitudinal limiting fixing frame (10).

8. The thermal insulation mortar processing method according to claim 7, wherein a separation frame (16) is fixed at the lower end of the separation adding table (14), a plurality of extrusion pipes (17) are fixed in the separation frame (16), a rubber preparation bin is arranged in the upper end of the separation adding table (14), and the extrusion pipes (17) are communicated with the rubber preparation bin.

9. The thermal insulation mortar processing method according to claim 8, wherein an extrusion thread driver (18) is fixed at the side end of the separation adding table (14), and the extrusion thread driver (18) drives the extrusion column platform (19) to longitudinally limit and slide on the separation adding table (14) through thread matching.

10. The thermal insulation mortar processing method according to claim 9, wherein a plurality of extrusion columns are fixed at the lower end of the extrusion column platform (19), and the extrusion columns are inserted into the extrusion pipes (17).