CN213273560U - Gypsum model rapid draing device for architectural design - Google Patents

Abstract

The utility model discloses a gypsum model quick drying device for architectural design, its technical scheme is: including interior casing, interior casing outer wall fixed mounting dead lever, the dead lever is kept away from the one end fixed connection shell body of interior casing, the arc wall has been seted up on the interior casing outer wall, be equipped with the heating pipe in the arc wall, the heating pipe is kept away from the butt arc fixing clip of arc wall inner wall, the beneficial effects of the utility model are that: nine groups of heating pipes are distributed at equal intervals, so that the inner shell is uniformly heated, and the temperature in the inner shell is as uniform as possible; the air-blower is through the inside blast air of the rotatory air duct of making a round trip to interior casing for the inside heat of interior casing can not gather, makes the gypsum model be heated mildly and even, has again to carry out air-dried effect to the gypsum model, has effectively avoided the gypsum model to be heated inhomogeneous, has avoided the great condition of gypsum model drying rate difference everywhere.

Description

Gypsum model rapid draing device for architectural design

Technical Field

The utility model relates to a gypsum model stoving technical field, concretely relates to gypsum model quick drying device for architectural design.

Background

The building design means that before the building is built, a designer makes a general idea of the problems existing or possibly occurring in the construction process and the use process in advance according to the construction task, plans a method and a scheme for solving the problems, expresses the problems by using paper and documents as a common basis for the mutual cooperation of material preparation, construction organization work and various work types in the manufacturing and building work, is convenient for the whole project to be uniformly and smoothly carried out within a preset investment limit range according to a carefully considered preset scheme, and ensures that the built building fully meets various requirements and applications expected by users and society, along with the development of the society and the progress of scientific technology, the content of the building and the problems to be solved are more and more complex, related subjects are more and more, and the building design concept of a designer is conveniently and intuitively understood, the building designer will often adopt the mode of gypsum model, construct the building of design, and the gypsum model who constructs need dry to guarantee the fastening nature and the long-time storage nature of the gypsum model who constructs.

Present gypsum model quick drying device through placing the gypsum model on placing the board, the gypsum model can not take place to remove at the in-process of drying, and the stoving incasement temperature everywhere can not be identical, therefore everywhere of model is heated inhomogeneously to different models often are not the completion of drying simultaneously, use inconvenient.

Therefore, the invention is necessary to develop a rapid drying device for gypsum models for building design.

SUMMERY OF THE UTILITY MODEL

For this, the utility model provides a gypsum model quick drying device for architectural design rises and descends through setting up electric telescopic handle electric gypsum model to it is rotatory to drive the gypsum model with servo motor one, makes gypsum model exchange position each other, and servo motor two drive the air duct incessantly to blow to the all directions, makes the gypsum model be heated everywhere evenly, has solved the not enough of above-mentioned current gypsum model quick drying device.

In order to achieve the above object, the present invention provides the following technical solutions:

a gypsum model quick drying device for architectural design comprises an inner shell, wherein a fixed rod is fixedly installed on the outer wall of the inner shell, one end of the fixed rod, which is far away from the inner shell, is fixedly connected with an outer shell, an arc-shaped groove is formed in the outer wall of the inner shell, a heating pipe is arranged in the arc-shaped groove, the heating pipe is far away from an arc-shaped fixed clamp of the inner wall of the arc-shaped groove, the tops of the outer shell and the inner shell are fixedly connected with an electric telescopic rod through a bearing, the bottom of the electric telescopic rod is fixedly connected with an inner column through a bolt, the bottom of the inner column is integrally formed with a first placing plate, the top of the first placing plate is provided with a first placing groove, the bottoms at two ends of the first placing groove are fixedly installed with sleeves, the inner wall at the bottom of the sleeve, the output of electric telescopic handle top fixed connection servo motor one, shell top fixed mounting support, support right-hand member top fixed mounting dehumidifier, shell top right-hand member fixed mounting servo motor two, servo motor two output end fixed connection pivot, the action wheel is cup jointed to the pivot outer wall, the action wheel meshing is connected from the driving wheel, cup joint the air duct from the driving wheel inner wall, the venthole has been seted up on the air duct, bearing fixed connection is passed through at the air duct both ends shell body and interior casing, air duct fixed connection hose, the hose is kept away from the one end fixed connection air-blower output of air duct.

Preferably, the arc-shaped grooves are at least provided with nine groups, and the nine groups of arc-shaped grooves are distributed on the outer wall of the inner shell at equal intervals.

Preferably, an internal thread through hole I is formed in the arc fixing clamp, an internal thread hole is formed in the inner shell, and the arc fixing clamp is connected with the inner shell through a bolt.

Preferably, the electric telescopic rod is fixedly connected with the support, the outer shell and the inner shell through a bearing, and the dehumidifier is communicated with the inside of the dehumidifier through a hose.

Preferably, the gas-guide tube is provided with two groups, and the heating tube is provided with at least nine groups.

Preferably, the bottom of the electric telescopic rod is provided with a second internal thread through hole, the bottom of the electric telescopic rod is fixedly connected with a mounting seat through a bolt, and the mounting seat is provided with a rectangular groove and a third internal thread through hole.

The utility model has the advantages that:

if the gypsum model is small, placing the gypsum model in a first placing groove on a first board, limiting the gypsum model by the first placing groove, switching on a power supply of nine groups of heating pipes, transmitting heat generated by the heating pipes into the inner shell through the inner shell to heat the gypsum model, starting an air blower, blowing air into the inner shell through a hose, an air duct and an air outlet hole to make the temperature inside the inner shell uniform, and simultaneously air-drying the gypsum model; the placing plate I and the placing plate II are used for placing smaller and larger gypsum models respectively, and the gypsum models with different sizes can be dried by classified placement; nine groups of heating pipes are distributed at equal intervals, so that the inner shell is uniformly heated, and the temperature in the inner shell is as uniform as possible; the air blower blows air to the interior of the inner shell through the air guide pipe which rotates back and forth, so that heat in the interior of the inner shell cannot be gathered, the local temperature of gypsum cannot be too high, the local temperature is too low, the gypsum model is heated mildly and uniformly, and the effect of air drying the gypsum model is achieved;

starting a servo motor II, wherein the servo motor II drives active rotation through a rotating shaft, a driving wheel drives a meshed driven wheel to rotate, the driven wheel drives an air guide pipe to rotate forwards, the air guide pipe is driven to rotate forwards, the servo motor II drives the air guide pipe to rotate backwards, air is blown to each part of the gypsum model, a servo motor I is started, and the servo motor I drives an electric telescopic rod to rotate, so that the gypsum model is driven to rotate, each part of the gypsum model is uniformly heated, and if the gypsum model is large, the gypsum model can be placed in a placing groove II on a placing plate II with a large space; the gypsum model is in the stoving in-process, and continuous up-and-down motion and rotation have effectively avoided the gypsum model to be heated inhomogeneous, have avoided the great condition of drying speed difference everywhere of gypsum model.

Drawings

Fig. 1 is a schematic structural diagram provided in embodiment 1 of the present invention;

fig. 2 is an enlarged view of a position a provided in embodiment 1 of the present invention;

fig. 3 is a schematic structural diagram provided in embodiment 2 of the present invention;

fig. 4 is an enlarged view of a position B provided in embodiment 2 of the present invention.

In the figure: the outer shell body 1, interior casing 2, the dead lever 3, place two 4 of board, sleeve 5, montant 6, place one 7 of board, a standing groove 8, inslot post 9, follow driving wheel 10, action wheel 11, two 12 servo motor, pivot 13, dehumidifier 14, servo motor 15, support 16, air-blower 17, hose 18, air duct 19, venthole 20, two 21 of standing groove, electric telescopic handle 22, heating pipe 23, arc fixing clip 24, internal thread hole 25, internal thread through-hole 26, arc 27, mount pad 28, internal thread through-hole two 29, rectangular channel 30, internal thread through-hole three 31.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Example 1:

referring to the attached drawings 1-2 of the specification, the gypsum model quick drying device for architectural design in the embodiment comprises an inner shell 2, a fixed rod 3 is fixedly installed on the outer wall of the inner shell 2, one end of the fixed rod 3, far away from the inner shell 2, is fixedly connected with an outer shell 1, an arc-shaped groove 27 is formed in the outer wall of the inner shell 2, a heating pipe 23 is arranged in the arc-shaped groove 27, the heating pipe 23 is far away from an abutting arc-shaped fixing clamp 24 on the inner wall of the arc-shaped groove 27, the tops of the outer shell 1 and the inner shell 2 are fixedly connected with an electric telescopic rod 22 through a bearing, the bottom of the electric telescopic rod 22 is fixedly connected with a connecting groove inner column 9 through a bolt, a placing plate I7 is integrally formed at the bottom of the groove inner column 9, a placing groove I8 is formed at the top of the placing plate I7, the bottom of the vertical rod 6 is provided with the sleeve 5, the lower part of the sleeve 5 is in threaded connection with a second placing plate 4, the top of the second placing plate 4 is provided with a second placing groove 21, the top of the electric telescopic rod 22 is fixedly connected with the output end of the servo motor I15, the top of the shell 1 is fixedly provided with a bracket 16, a dehumidifier 14 is fixedly arranged above the right end of the bracket 16, a second servo motor 12 is fixedly arranged at the right end of the top of the shell 1, the output end of the second servo motor 12 is fixedly connected with a rotating shaft 13, the outer wall of the rotating shaft 13 is sleeved with a driving wheel 11, the driving wheel 11 is engaged with the driven wheel 10, the inner wall of the driven wheel 10 is sleeved with the air duct 19, the air duct 19 is provided with an air outlet 20, two ends of the air duct 19 are fixedly connected with the outer shell 1 and the inner shell 2 through bearings, the air duct 19 is fixedly connected with a hose 18, and one end of the hose 18, which is far away from the air duct 19, is fixedly connected with the output end of the blower 17; the outer shell 1 has the functions of preserving heat of the inner shell 2, reducing the internal temperature loss of the inner shell 2, and simultaneously playing a role of protection to prevent the inner shell 2 from directly contacting with the outside to scald people; the fixing rod 3 is used for connecting the outer shell 1 and the inner shell 2 together; the second placing plate 4 is used for placing a larger plaster model; the sleeve 5 is used for installing the second placing plate 4 below the first placing plate 7, so that the second placing plate 4 can move along with the first placing plate 7; the first placing groove 8 and the second placing groove 21 are used for limiting the gypsum model, so that the gypsum model is prevented from moving when moving; the model of the dehumidifier 14 is set as DH20EH, which is used for discharging the moisture of the gypsum model in the drying process, so that the gypsum model is dried more quickly; the second servo motor 12 is set to be JSF 42-3-30-AS-1000 and is used for driving the air duct 19 to rotate; the first servo motor 15 is set to be JSF60-15-30-CF-1000 and is used for driving the gypsum model to rotate; the electric telescopic rod 22 is set to YNT-03 and is used for driving the gypsum model to move up and down; the blower 17 is provided as HTRG-400 for blowing air to the inside of the inner case 2 to make the temperature uniform throughout the inner case and to air-dry the plaster model.

Furthermore, the arc-shaped grooves 27 are at least provided with nine groups, and the nine groups of arc-shaped grooves 27 are distributed on the outer wall of the inner shell 2 at equal intervals; the arc-shaped slots 27 are used for installing the heating pipe 23 and thinning the inner shell 2 at the same time, so that the heat transfer efficiency of the heating pipe 23 is higher, and the arc-shaped slots 27 distributed at equal intervals are used for enabling the heating pipe 23 to be distributed at equal intervals and helping to make the temperature in the inner shell 2 uniform.

Furthermore, an internal thread through hole 26 is formed in the arc-shaped fixing clamp 24, an internal thread hole 25 is formed in the inner shell 2, and the arc-shaped fixing clamp 24 is connected with the inner shell 2 through a bolt; the effective heating pipe 23 of arc fixing clip 24 is fixed, makes things convenient for the dismantlement and the installation of heating pipe 23.

Further, the electric telescopic rod 22 is fixedly connected with the bracket 16, the outer shell 1 and the inner shell 2 through bearings, and the dehumidifier 14 is communicated with the inside of the dehumidifier 14 through a hose; so that the electric telescopic rod 22 can rotate along with the output end of the first servo motor 15, and the gypsum model is heated more uniformly.

Furthermore, the gas-guide tubes 19 are provided with two groups, and the heating tubes 23 are provided with at least nine groups; the heating pipes 23 are equidistantly distributed at the arc-shaped slots 27 to help the temperature inside the inner shell 2 to be uniform.

The implementation scenario is specifically as follows: when the utility model is used, if the gypsum model is small, the gypsum model is placed in the placing groove I8 on the first gypsum model placing plate 7, the placing groove I8 limits the gypsum model, the power supply of nine groups of heating pipes 23 is switched on, the heat generated by the heating pipes 23 is transmitted to the inner shell 2 through the inner shell 2 to heat the gypsum model, the air blower 17 is started, air is blown into the inner shell 2 through the hose 18, the air duct 19 and the air outlet hole 20, the temperature in the inner shell 2 is uniform, the gypsum model is simultaneously air-dried, the servo motor II 12 is started, the servo motor II 12 drives the initiative 11 to rotate through the rotating shaft 13, the driving wheel 11 drives the meshed driven wheel 10 to rotate, the driven wheel 10 drives the air duct 19 to rotate positively, the air duct 19 rotates for about 60 degrees, the servo motor II 12 drives the air duct 19 to rotate reversely, air is blown everywhere to the, servo motor 15 drives electric telescopic handle 22 rotatory to it is rotatory to drive the gypsum model, thereby makes the gypsum model be heated everywhere evenly, if the gypsum model is when great, can place the gypsum model in two 21 of the great standing groove on two 4 of board of placing in space.

Example 2:

referring to the attached figures 3-4 of the specification, the difference from the embodiment 1 is that: the bottom of the electric telescopic rod 22 is provided with a second internal thread through hole 29, the bottom of the electric telescopic rod 22 is fixedly connected with a mounting seat 28 through a bolt, and the mounting seat 28 is provided with a rectangular groove 30 and a third internal thread through hole 31;

the implementation scenario is specifically as follows:

when the utility model is used, if the gypsum model is small, the gypsum model is placed in the placing groove I8 on the first gypsum model placing plate 7, the placing groove I8 limits the gypsum model, the power supply of nine groups of heating pipes 23 is switched on, the heat generated by the heating pipes 23 is transmitted to the inner shell 2 through the inner shell 2 to heat the gypsum model, the air blower 17 is started, air is blown into the inner shell 2 through the hose 18, the air duct 19 and the air outlet hole 20, the temperature in the inner shell 2 is uniform, the gypsum model is simultaneously dried, the servo motor II 12 is started, the servo motor II 12 drives the initiative 11 to rotate through the rotating shaft 13, the driving wheel 11 drives the meshed driven wheel 10 to rotate, the driven wheel 10 drives the air duct 19 to rotate positively, the air duct 19 rotates for about 60 degrees, the servo motor II 12 drives the air duct 19 to rotate reversely, the air duct 19 rotates back and forth, starting a first servo motor 15, a first servo motor 15 drives an electric telescopic handle 22 to rotate, the electric telescopic handle 22 drives a gypsum model to rotate, thereby enabling the gypsum model to be heated uniformly everywhere, if the gypsum model is large, placing grooves two 21 on two 4 placing plates with large space can be placed on the gypsum model, when a first 7 placing plate needs to be dismantled, bolts connecting a mounting seat 28 and placing the first 7 placing plate are dismantled, and the mounting seat 28 and the first 7 placing plate are convenient to dismantle and install.

The above description is only a preferred embodiment of the present invention, and any person skilled in the art may modify the present invention or modify it into an equivalent technical solution by using the technical solutions described above. Therefore, any simple modifications or equivalent replacements made according to the technical solution of the present invention belong to the scope of the claimed invention as far as possible.

Claims (6)

1. A gypsum model rapid drying device for architectural design, includes interior casing (2), its characterized in that: the fixing rod (3) is fixedly installed on the outer wall of the inner shell (2), one end, far away from the inner shell (2), of the fixing rod (3) is fixedly connected with the outer shell (1), an arc-shaped groove (27) is formed in the outer wall of the inner shell (2), a heating pipe (23) is arranged in the arc-shaped groove (27), the heating pipe (23) is far away from an arc-shaped fixing clamp (24) of the inner wall of the arc-shaped groove (27), the tops of the outer shell (1) and the inner shell (2) are fixedly connected with an electric telescopic rod (22) through bearings, the bottom of the electric telescopic rod (22) is fixedly connected with a connecting groove inner column (9) through bolts, a placing plate I (7) is integrally formed at the bottom of the groove inner column (9), a placing groove I (8) is formed at the top of the placing plate I (7), sleeves (5) are fixedly installed at the, the bottom of the vertical rod (6) is connected with the sleeve (5) in a threaded manner, the sleeve (5) is connected with a placing plate II (4) in a threaded manner, the top of the placing plate II (4) is provided with a placing groove II (21), the top of the electric telescopic rod (22) is fixedly connected with the output end of a servo motor I (15), the top of the outer shell (1) is fixedly provided with a support (16), the upper part of the right end of the support (16) is fixedly provided with a dehumidifier (14), the top of the outer shell (1) is fixedly provided with a servo motor II (12), the output end of the servo motor II (12) is fixedly connected with a rotating shaft (13), the outer wall of the rotating shaft (13) is sleeved with a driving wheel (11), the driving wheel (11) is meshed with a driven wheel (10), the inner wall of the driven wheel (10) is sleeved with an air duct (19), the air outlet hole (20) is formed, the air guide pipe (19) is fixedly connected with a hose (18), and one end, far away from the air guide pipe (19), of the hose (18) is fixedly connected with the output end of the air blower (17).

2. The rapid drying device for gypsum patterns for architectural design according to claim 1, wherein: the arc-shaped grooves (27) are at least provided with nine groups, and the nine groups of arc-shaped grooves (27) are distributed on the outer wall of the inner shell (2) at equal intervals.

3. The rapid drying device for gypsum patterns for architectural design according to claim 1, wherein: the arc fixing clamp (24) is provided with a first internal thread through hole (26), the inner shell (2) is provided with an internal thread hole (25), and the arc fixing clamp (24) is connected with the inner shell (2) through a bolt.

4. The rapid drying device for gypsum patterns for architectural design according to claim 1, wherein: the electric telescopic rod (22) is fixedly connected with the support (16), the outer shell (1) and the inner shell (2) through a bearing, and the dehumidifier (14) is communicated with the inside of the dehumidifier (14) through a hose.

5. The rapid drying device for gypsum patterns for architectural design according to claim 1, wherein: the gas-guide tubes (19) are provided with two groups, and the heating tubes (23) are at least provided with nine groups.

6. The rapid drying device for gypsum patterns for architectural design according to claim 1, wherein: an internal thread through hole II (29) is formed in the bottom of the electric telescopic rod (22), the bottom of the electric telescopic rod (22) is fixedly connected with a mounting seat (28) through a bolt, and a rectangular groove (30) and an internal thread through hole III (31) are formed in the mounting seat (28).

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