CN217226054U - Concrete hollow brick overturning and demoulding mechanism - Google Patents
Concrete hollow brick overturning and demoulding mechanism Download PDFInfo
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- CN217226054U CN217226054U CN202220068734.3U CN202220068734U CN217226054U CN 217226054 U CN217226054 U CN 217226054U CN 202220068734 U CN202220068734 U CN 202220068734U CN 217226054 U CN217226054 U CN 217226054U
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Abstract
The application provides concrete hollow brick upset demoulding mechanism belongs to concrete hollow brick technical field. The overturning and demolding mechanism for the concrete hollow brick comprises a supporting piece and a driving assembly. Support piece is including supporting shell and upset cover, spacing one end all run through in the bearing shell splint with support the head and extend to in the bearing shell, bearing shell symmetry sliding connection in the support shell, just the equal screw thread of bearing shell cup joint in the output axle head of double-shaft rotary machine, the equal fixed mounting of upset portion in the upset cover. Through the design of this device, the design of the conventional concrete hollow brick upset demoulding mechanism of global design optimization, through the cooperation of biax commentaries on classics machine, accepting portion and upset portion, realize changing the mould of different models, simultaneously, through accepting shell, splint and spacing axle design, the mould of the different models of adaptation of being convenient for, global design reduces and uses the limitation.
Description
Technical Field
The application relates to the technical field of concrete hollow bricks, in particular to a concrete hollow brick overturning and demolding mechanism.
Background
The concrete hollow brick has the characteristics of light weight, fire resistance, sound insulation, heat preservation, permeability resistance, earthquake resistance, durability and the like, the concrete hollow brick is pollution-free, energy-saving and consumption-reducing, is a green environment-friendly building material required by the current generation, and becomes an important component in the novel wall material of the current generation, at present, the concrete hollow brick is basically produced by a mould, the production processes are different according to the types of the mould, one of the production modes through the turnover mould is that, referring to the design of a conventional concrete hollow brick turnover demoulding mechanism, the clamping turnover arm is basically driven by a travelling crane to move and lift, the mould is limited and turned over through the clamping turnover arm, however, in the practical use discovery, the interval of two centre gripping upset arms can't be adjusted, leads to when the production mould of the different models of follow-up change, and two centre gripping upset arms can't be used to its adaptation, and global design has certain limitation.
SUMMERY OF THE UTILITY MODEL
In order to compensate above not enough, this application provides concrete hollow brick upset demoulding mechanism, aims at improving the unable spacing of adjusting of conventional centre gripping upset arm, makes it unable problem to the production mould adaptation use of different models.
The embodiment of the application provides a concrete hollow brick upset demoulding mechanism, including support piece and drive assembly.
Support piece including supporting shell and upset cover, upset cover symmetry set up in support the shell bottom, just the equal fixedly connected with in upset cover upper surface supports the head, drive assembly includes that the biax changes machine, accepting portion and upset portion, accepting portion includes accepting shell, splint and spacing axle, splint symmetry sliding connection in accept in the shell, splint with accept shell bolted connection, and two the splint lateral wall all with support the laminating of first outer wall, spacing axle one end all run through in accept the shell splint with support the head and extend to in the accept shell, accept shell symmetry sliding connection in support in the shell, just it all the screw thread of accept the shell cup joints in biax changes machine output shaft end, the equal fixed mounting of upset portion in the upset cover.
In the implementation process, the device is driven by an external travelling crane to move up and down, so that the device can be driven to finally drive a mould to perform side turning and demoulding, when in actual use, the device is sleeved at the position of the side handle of the external mould by the overturning part, the device is driven by the external travelling crane to move, ascend and descend, the mould is driven by the overturning part to slowly overturn, so that the mould is overturned for 90 degrees and finally drives the side mould to move by the device and the travelling crane, demoulding with a bottom mould is realized, when in actual use, the pin joint design of the support joint is realized by matching of the two clamping plates and the limiting shaft, so that the turnover cover with different models can be conveniently replaced, so that the subsequent moulds with different models can be conveniently adapted and used, meanwhile, the bearing shell and the turnover cover are driven to slide by rotating the double-shaft rotating machine, the space between the two turnover covers is adjusted, and the moulds with different models can be integrally replaced in an omnibearing way, through the design of this device, the design of conventional concrete hollow brick upset demoulding mechanism is optimized in global design, changes the machine through the biax, the cooperation of accepting portion and upset portion, realizes changing the mould of different models, simultaneously, through accepting shell, splint and spacing axle design, the mould of the different models of adaptation of being convenient for, global design reduces and uses the limitation.
In a specific embodiment, the outer wall of the supporting shell is symmetrically provided with notches, and the notches and the bearing shell are correspondingly arranged.
In the implementation process, through the notch design, the pin joint design and the replacement and installation can be released through the notch when the turnover cover is replaced subsequently.
In a specific implementation scheme, the double-shaft rotating machine comprises a first motor and a screw rod, one end of the screw rod is rotatably connected in the supporting shell, and the other end of the screw rod is fixedly connected to the output shaft end of the first motor.
In the implementation process, the first motor and the screw rod integrally form a double-shaft rotating machine, the screw rod is driven to rotate by the first motor, and the first motor is a double-shaft motor.
In a specific implementation scheme, the bearings are symmetrically installed on the inner wall of the supporting shell, one end of the screw rod is rotatably connected in the bearings, the upper surface of the bearing shell is fixedly connected with a fixed block, the fixed block is slidably connected in the supporting shell, and the fixed block is sleeved outside the screw rod in a threaded manner.
In the implementation process, through the bearing design, the design of connecting one end of the screw rod in a rotating mode is realized through the integral design, and meanwhile, through the design of the fixing block, the screw rod is finally driven to rotate through the first motor so as to drive the fixing block to move.
In a specific embodiment, magnets are symmetrically arranged in the bearing shell, and the side wall of each magnet is adsorbed to one end of the limiting shaft.
In the implementation process, the magnet is designed, the whole design is strengthened to limit the limiting shaft, and the limiting shaft is prevented from shaking and moving in the use process.
In a specific embodiment, the turning part comprises a second motor and a clamping sleeve, the second motors are fixedly arranged in the turning cover, and the clamping sleeve is fixedly connected to the output shaft ends of the second motors.
In the above-mentioned realization process, drive the cutting ferrule through the second motor and rotate, and then realize the upset to the mould, during the in-service use, this device is fixed in outside driving bottom.
In a specific embodiment, the side wall of the cutting sleeve is provided with a clamping groove.
In the above-mentioned realization process, through the draw-in groove design, the global design realizes cup jointing to outside mould through the cutting ferrule, simultaneously, drives the cutting ferrule through the second motor and rotates.
In a specific embodiment, the clamping sleeve side wall is symmetrically and fixedly connected with limiting columns, the side wall of the turnover cover is provided with limiting grooves, and the limiting columns are slidably connected in the limiting grooves.
In above-mentioned realization in-process, through spacing post design, when being convenient for in-service use, strengthen the cutting ferrule holding power, the spacing groove is circular.
In a specific embodiment, the upper surfaces of the clamping plates are fixedly connected with mounting blocks which are slidably connected in the bearing shell, and the clamping plates are connected in the bearing shell through the mounting blocks by bolts.
In the above-mentioned realization process, through the installation piece design, the bolt fastening is realized in global design, simultaneously, accepts and is located the equal interval distribution in installation piece bolted connection position in the shell and has the bolt hole, and splint are the design of T type.
In a specific embodiment, through holes are formed in the side wall of the bearing shell at the penetrating positions of the limiting shafts.
In the implementation process, through the design of the through hole, the whole limiting shaft is convenient to penetrate through and pin-connected.
Drawings
In order to more clearly explain the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that for those skilled in the art, other related drawings can be obtained from these drawings without inventive effort.
FIG. 1 is a schematic front view of an embodiment of the present disclosure;
FIG. 2 is a schematic sectional front view structure provided in an embodiment of the present application;
fig. 3 is a schematic front sectional view of a receiving portion according to an embodiment of the present disclosure;
fig. 4 is an enlarged structure diagram of a ferrule side view provided in the embodiment of the present application.
In the figure: 100-a support; 110-a support shell; 111-a bearing; 112-notch; 120-flip cover; 121-support head; 122-a limit groove; 200-a drive assembly; 210-double-shaft rotating machine; 211-a first motor; 212-a screw rod; 220-a receiving part; 221-a receiving shell; 2211-fixed block; 2212 a magnet; 2213-through holes; 222-a clamping plate; 2221-mounting block; 223-a limit shaft; 230-a turning part; 231-a second motor; 232-clamping sleeve; 2321-card slot; 2322-limit column.
Detailed Description
The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.
To make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art without any inventive work based on the embodiments in the present application are within the scope of protection of the present application.
Referring to fig. 1, the present application provides a concrete air brick turnover demolding mechanism, which includes a support member 100 and a driving assembly 200.
Wherein, realize supporting fixedly through support piece 100, simultaneously, realize this device and outside driving fixed connection, realize upset and regulation through drive assembly 200.
Referring to fig. 1 and 2, the supporting member 100 includes a supporting shell 110 and an overturning cover 120, the overturning cover 120 is symmetrically disposed at the bottom of the supporting shell 110, and the upper surface of the overturning cover 120 is fixedly connected with supporting heads 121, the outer wall of the supporting shell 110 is symmetrically provided with notches 112, the notches 112 and the receiving shell 221 are correspondingly disposed, by the design of the notches 112, the overall design is convenient for the pin joint release design and the replacement and installation through the notches 112 when the overturning cover 120 is subsequently replaced, bearings 111 are symmetrically mounted on the inner wall of the supporting shell 110, one end of the screw rod 212 is rotatably connected in the bearings 111, the upper surface of the receiving shell 221 is fixedly connected with a fixing block 2211, the fixing block 2211 is slidably connected in the supporting shell 110, and the fixing block 2211 is threadedly sleeved outside the screw rod 212, by the design of the bearings 111, the overall design realizes the design that one end of the screw rod 212 is rotatably connected, and at the same time, the fixing block 2211 is designed to finally drive the screw rod 212 to rotate through the first motor 211 to drive the fixing block 2211 to move, is fixedly connected with an external traveling crane through the upper surface of the supporting shell 110.
Referring to fig. 1, 2, 3 and 4, the driving assembly 200 includes a dual spindle rotating machine 210, a receiving portion 220 and a reversing portion 230, the receiving portion 220 includes a receiving shell 221, a clamping plate 222 and a limiting shaft 223, the clamping plate 222 is symmetrically slidably connected in the receiving shell 221, the clamping plate 222 is bolted to the receiving shell 221, and the two clamping plates 222 are attached to the outer wall of the supporting head 121, one end of the limiting shaft 223 penetrates through the receiving shell 221, the clamping plate 222 and the supporting head 121 and extends into the receiving shell 221, through holes 2213 are formed in the positions where the limiting shaft 223 penetrates through the side wall of the receiving shell 221, the limiting shaft 223 is integrally and conveniently penetrated and pinned through by the through holes 2213, the receiving shell 221 is symmetrically slidably connected in the supporting shell 110, and the receiving shell 221 is screwed to the output shaft of the dual spindle rotating machine 210, the dual spindle rotating machine 210 includes a first motor 211 and a lead screw 212, one end of the lead screw 212 is rotatably connected in the supporting shell 110, and the other end of the lead screw 212 is fixedly connected to the output shaft end of the first motor 211, through first motor 211 and the whole biax of constitution of lead screw 212 changes machine 210, it rotates to drive lead screw 212 through first motor 211, first motor 211 is the biax motor, magnet 2212 is installed to the symmetry in the accepting shell 221, magnet 2212 lateral wall adsorbs with spacing axle 223 one end, through the design of magnet 2212, it is spacing to spacing axle 223 to global design enhancement, make it avoid spacing axle 223 to rock and then remove in the use, the equal fixedly connected with installation piece 2221 in splint 222 upper surface, installation piece 2221 sliding connection is in accepting shell 221, splint 222 passes through installation piece 2221 bolted connection in accepting shell 221, through installation piece 2221 design, the bolt fastening is realized to global design, simultaneously, it has the equal interval distribution in installation piece 2221 bolted connection position to be located in accepting shell 221, splint 222 is the design of T type bolt hole.
In the present application, the turning part 230 is fixedly installed in the turning cover 120, the turning part 230 includes a second motor 231 and a sleeve 232, the second motor 231 is fixedly installed in the turning cover 120, the sleeve 232 is fixedly connected to an output shaft end of the second motor 231, the sleeve 232 is driven to rotate by the second motor 231, thereby realizing the turnover of the die, when in actual use, the device is fixed at the bottom of an external travelling crane, the side wall of the cutting sleeve 232 is provided with a clamping groove 2321, by the design of the clamping groove 2321, the whole design realizes the sleeve joint of the external mould through the clamping sleeve 232, meanwhile, the second motor 231 drives the cutting sleeve 232 to rotate, the side wall of the cutting sleeve 232 is symmetrically and fixedly connected with the limiting posts 2322, the side wall of the turnover cover 120 is provided with the limiting groove 122, the limiting posts 2322 are slidably connected in the limiting groove 122, through spacing post 2322 design, when being convenient for in-service use, strengthen cutting ferrule 232 holding power, spacing groove 122 is circular.
Specifically, the working principle of the concrete hollow brick overturning and demolding mechanism is as follows: when in use, the external travelling crane drives the device to move up and down, so that the device is convenient to finally drive a mould to perform side turning and demoulding, the clamping sleeve 232 is sleeved at the position of the side handle of the external mould through the clamping groove 2321, the device is driven by the external travelling crane to move, ascend and descend, the mould is driven by the second motor 231 to slowly overturn, the mould is overturned for 90 degrees, and finally the side mould is driven by the device and the travelling crane to move, so that demoulding with a bottom mould is realized, during actual use, the pin joint design of the support head 121 is realized through the matching of the two clamping plates 222 and the limiting shaft 223, so that the turnover cover 120 with different models can be conveniently replaced, so that subsequent moulds with different models can be conveniently used in a matching way, meanwhile, the first motor 211 drives the screw rod 212 to rotate so as to drive the bearing shell 221 and the turnover cover 120 to slide, the adjustment of the distance between the two turnover covers 120 is realized, and the omnibearing replacement of moulds with different models is integrally realized, through the design of this device, the design of conventional concrete air brick upset demoulding mechanism is optimized in global design, changes the mould of different models through biax commentaries on classics machine 210, accepting portion 220 and the cooperation of upset portion 230, realizes changing, simultaneously, through accepting shell 221, splint 222 and spacing axle 223 design, the mould of the different models of adaptation of being convenient for, global design reduces and uses the limitation.
It should be noted that the specific model specifications of the first motor 211 and the second motor 231 need to be determined by type selection according to the actual specification of the device, and the specific type selection calculation method adopts the prior art, so detailed description is omitted.
The power supply of the first motor 211 and the second motor 231 and the principle thereof will be apparent to those skilled in the art and will not be described in detail herein.
The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.
The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.
Claims (10)
1. A concrete hollow brick overturning and demoulding mechanism is characterized by comprising
The supporting piece (100) comprises a supporting shell (110) and a turnover cover (120), the turnover cover (120) is symmetrically arranged at the bottom of the supporting shell (110), and supporting heads (121) are fixedly connected to the upper surface of the turnover cover (120);
a driving assembly (200), wherein the driving assembly (200) comprises a double-shaft rotating machine (210), a bearing part (220) and an overturning part (230), the bearing part (220) comprises a bearing shell (221), a clamping plate (222) and a limiting shaft (223), the clamping plates (222) are symmetrically and slidably connected into the bearing shell (221), the clamping plates (222) are connected with the bearing shell (221) through bolts, and the side walls of the two clamping plates (222) are jointed with the outer wall of the supporting head (121), one end of the limit shaft (223) penetrates through the bearing shell (221), the clamping plate (222) and the support head (121) and extends into the bearing shell (221), the bearing shell (221) is symmetrically connected in the supporting shell (110) in a sliding way, and the bearing shells (221) are all in threaded sleeve joint with the output shaft end of the double-shaft rotating machine (210), the overturning parts (230) are fixedly arranged in the overturning cover (120).
2. The concrete hollow brick overturning and demolding mechanism according to claim 1, wherein the outer wall of the supporting shell (110) is symmetrically provided with notches (112), and the notches (112) and the receiving shell (221) are correspondingly arranged.
3. The concrete hollow brick overturning and demolding mechanism according to claim 1, wherein the double-shaft rotating machine (210) comprises a first motor (211) and a screw rod (212), one end of the screw rod (212) is rotatably connected into the supporting shell (110), and the other end of the screw rod (212) is fixedly connected to the output shaft end of the first motor (211).
4. The concrete hollow brick overturning and demolding mechanism according to claim 3, wherein bearings (111) are symmetrically installed on the inner wall of the supporting shell (110), one end of the screw rod (212) is rotatably connected into the bearings (111), the upper surface of the bearing shell (221) is fixedly connected with a fixing block (2211), the fixing block (2211) is slidably connected into the supporting shell (110), and the fixing block (2211) is in threaded sleeve connection with the outside of the screw rod (212).
5. The concrete hollow brick overturning and demolding mechanism according to claim 1, wherein magnets (2212) are symmetrically installed in the bearing shell (221), and the side walls of the magnets (2212) are adsorbed to one end of the limiting shaft (223).
6. The concrete core brick overturning and demolding mechanism according to claim 1, wherein the overturning part (230) comprises a second motor (231) and clamping sleeves (232), the second motor (231) is fixedly installed in the overturning cover (120), and the clamping sleeves (232) are fixedly connected to output shaft ends of the second motor (231).
7. The concrete hollow brick overturning and demolding mechanism according to claim 6, wherein a clamping groove (2321) is formed in the side wall of the clamping sleeve (232).
8. The concrete hollow brick overturning and demolding mechanism according to claim 6, wherein the side wall of the clamping sleeve (232) is symmetrically and fixedly connected with a limiting column (2322), the side wall of the overturning cover (120) is provided with a limiting groove (122), and the limiting column (2322) is slidably connected in the limiting groove (122).
9. A concrete hollow brick turnover demoulding mechanism according to claim 1, characterized in that the upper surfaces of the clamping plates (222) are fixedly connected with mounting blocks (2221), the mounting blocks (2221) are slidably connected in the bearing shell (221), and the clamping plates (222) are bolted in the bearing shell (221) through the mounting blocks (2221).
10. The concrete hollow brick overturning and demolding mechanism according to claim 1, wherein the side wall of the bearing shell (221) is provided with a through hole (2213) at the penetrating position of the limiting shaft (223).
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CN202220068734.3U CN217226054U (en) | 2022-01-12 | 2022-01-12 | Concrete hollow brick overturning and demoulding mechanism |
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CN202220068734.3U CN217226054U (en) | 2022-01-12 | 2022-01-12 | Concrete hollow brick overturning and demoulding mechanism |
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CN217226054U true CN217226054U (en) | 2022-08-19 |
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CN202220068734.3U Active CN217226054U (en) | 2022-01-12 | 2022-01-12 | Concrete hollow brick overturning and demoulding mechanism |
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