CN211903644U

CN211903644U - Three-dimensional drying device

Info

Publication number: CN211903644U
Application number: CN201922354738.9U
Authority: CN
Inventors: 梅连军; 韩树辉; 魏来
Original assignee: Shenzhen Textalk Graphic Technology Co ltd
Current assignee: Shenzhen Textalk Graphic Technology Co ltd
Priority date: 2019-12-24
Filing date: 2019-12-24
Publication date: 2020-11-10
Anticipated expiration: 2029-12-24

Abstract

The utility model provides a three-dimensional drying device, which comprises a heating frame body and a circulating transmission structure; the circulating transmission structure comprises an upper-layer net inlet transmission mechanism, a rising stacking transmission mechanism, a net frame transfer mechanism, a falling stacking transmission mechanism and an upper-layer net outlet transmission mechanism. The utility model discloses an in the heating framework, control each carrier net frame and circulate in step and remove, make the temperature that receives heat of every carrier net frame, the process of being heated and the mode of being heated keep unanimous basically, the time of being heated is invariable, very big having avoided because the temperature difference, whether it is even to be heated, the technological problem that external factors such as the residual temperature after the stop heating leads to, the colour difference scheduling problem that produces from this is avoided to utmost.

Description

Three-dimensional drying device

Technical Field

The utility model relates to a drying equipment technical field especially relates to a three-dimensional drying device.

Background

After the ready-made clothes printing fabric is treated by the printing pretreatment liquid, the ready-made clothes printing fabric can be printed only by drying.

Because the water content in the printing pretreatment liquid is very high, the fabric can be fully dried only by drying at a high temperature of 30 minutes, and then printing can be carried out.

The existing drying system needs low drying efficiency, and the efficiency of large-scale digital printing production is seriously influenced. If it is desired to increase the speed, a large space is required or the number of drying systems is increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the above-mentioned technical problem that exists among the prior art, provide a three-dimensional drying device, be applied to the stoving to the processing liquid before the stamp of locating the ready-made clothe printing surface fabric on the screen frame carrier, include:

the heating frame body is arranged in the circulating transmission structure in the heating frame body;

the circulating transmission structure comprises an upper-layer net inlet transmission mechanism, an ascending stacking transmission mechanism, a net frame transfer mechanism, a descending stacking transmission mechanism and an upper-layer net outlet transmission mechanism;

the upper-layer net inlet transmission mechanism and the upper-layer net outlet transmission mechanism are respectively arranged at two ends in the length direction in the heating frame body and are used for inputting and outputting the net frame carrier;

the ascending stacking transmission mechanism is arranged at the upper end of the upper-layer net inlet transmission mechanism, and the descending stacking transmission mechanism is arranged at the upper end of the upper-layer net outlet transmission mechanism;

the screen frame transfer mechanism is connected with the ascending stacking transmission mechanism and the descending stacking transmission mechanism and is arranged at the upper ends of the ascending stacking transmission mechanism and the descending stacking transmission mechanism; so that the upper net feeding transmission mechanism, the ascending stacking transmission mechanism, the net frame shifting mechanism, the descending stacking transmission mechanism and the upper net discharging transmission mechanism are sequentially connected to form a structure shaped like a Chinese character 'ji';

and a screen frame carrier loaded with the ready-made clothes printing fabric is moved in by the upper-layer screen inlet transmission mechanism, transferred to the screen frame transfer mechanism through the ascending stacking transmission mechanism, translated to the descending stacking transmission mechanism through the screen frame transfer mechanism, and moved out through the upper-layer screen outlet transmission mechanism after being transferred downwards.

Preferably, the heating frame body is provided with an outer frame body layer and an insulation cotton layer arranged in the frame body layer; the heating frame body is provided with an input pipeline for inputting hot air flow and an output pipeline for flowing out of the hot air flow.

Preferably, the upper-layer net inlet transmission mechanism and the upper-layer net outlet transmission mechanism are arranged in parallel, and the input transmission direction is consistent with the output transmission direction.

Preferably, the upper-layer net feeding transmission mechanism comprises a net feeding motor, a first driving transmission rod connected with the net feeding motor, and two first annular chain transmission mechanisms which are symmetrically and parallelly arranged and connected with the first driving transmission rod; the first annular chain transmission mechanism can synchronously rotate under the rotating power output by the net feeding motor;

the upper-layer net outlet transmission mechanism comprises a net outlet motor, a second driving transmission rod connected with the net outlet motor, and two second annular chain transmission mechanisms which are symmetrically and parallelly arranged and connected with the second driving transmission rod; the second annular chain transmission mechanism can synchronously rotate under the rotating power output by the net feeding motor.

Preferably, the ascending stacking transmission mechanism and the descending stacking transmission mechanism have opposite conveying directions for the screen frame carrier; wherein the content of the first and second substances,

the ascending stacking transmission mechanism is used for conveying the screen frame carrier output by the upper-layer screen inlet transmission mechanism into the screen frame transfer mechanism from bottom to top;

the descending stacking transmission mechanism is used for conveying the screen frame carrier output by the screen frame transfer mechanism into the upper-layer screen outlet transmission mechanism from top to bottom.

Preferably, each of the ascending stacking transmission mechanism and the descending stacking transmission mechanism comprises 4 traction moving components which are vertically and symmetrically arranged, and a plurality of supporting angle irons which are arranged on the traction moving components, so that in the ascending stacking transmission mechanism, the net frame carrier is lifted upwards to move through the corresponding supporting angle irons on the 4 traction moving components; and lifting the screen frame carrier to move downwards in the descending stacking transmission mechanism through corresponding bearing angle irons on 4 traction moving components.

Preferably, the supporting angle iron is an L-shaped supporting angle iron;

each bearing angle iron is provided with the corresponding bearing angle iron in other traction moving assemblies on the same horizontal plane.

Preferably, the lifting stacking transmission mechanism further comprises a lifting motor and two lifting transmission rods connected with the lifting motor,

the 4 traction moving assemblies are connected in pairs through a lifting transmission rod; so that under the driving of the lifting motor, based on the transmission of the lifting transmission rod, 4 traction moving components synchronously drive the bearing angle iron to move;

the descending stacking transmission mechanism also comprises a descending motor and two descending transmission rods connected with the descending motor,

the 4 traction moving assemblies are connected in pairs through a descending transmission rod; so that under the drive of descending motor, based on the transmission of descending transfer line, 4 pull the removal subassembly and drive in step the bearing angle bar removes.

Preferably, the screen frame transfer mechanism comprises a transfer motor, a first driving shaft connected with the transfer motor and arranged in the horizontal direction, and a second driving shaft far away from the first driving shaft;

gears are arranged on the first driving shaft and the second driving shaft, and a transfer chain is sleeved on the gear on the first driving shaft and the gear on the second driving shaft;

the screen frame transfer mechanism is also provided with a guide shaft which is perpendicular to the first driving shaft and has the length matched with the distance between the first driving shaft and the second driving shaft;

a push plate for pushing the screen frame carrier in the horizontal direction is arranged on the guide shaft; the push plate can horizontally move along the length direction of the guide shaft;

the push plate is provided with an engaging part which can be engaged with the transfer chain, so that under the driving of a transfer motor, the transfer chain rotates along with the first driving shaft and the second driving shaft synchronously, and the transfer chain drives the push plate engaged with the transfer chain to reciprocate along the guide shaft.

The utility model provides a three-dimensional drying device, through in the heating frame, will load the screen frame carrier of ready-made clothe printed fabric, by the upper strata advances the immigration of net drive mechanism, warp rising stack drive mechanism transmits extremely the screen frame moves and carries the mechanism, moves through the screen frame and carries the mechanism translation extremely decline stack drive mechanism, after the transmission downwards, through the upper strata goes out the net drive mechanism and shifts out. The utility model discloses an in the heating framework, control each carrier net frame and circulate in step and remove, make the temperature that receives heat of every carrier net frame, the process of being heated and the mode of being heated keep unanimous basically, the time of being heated is invariable, very big having avoided because the temperature difference, whether it is even to be heated, the technological problem that external factors such as the residual temperature after the stop heating leads to, the colour difference scheduling problem that produces from this is avoided to utmost.

Drawings

Fig. 1 is a schematic structural diagram of a three-dimensional drying device provided by an embodiment;

fig. 2 is a schematic structural diagram of a circulation transfer structure of a three-dimensional drying device according to an embodiment;

fig. 3 is a front end elevation view of a circulation transfer structure of the three-dimensional drying device provided by the embodiment;

fig. 4 is a top view of a circulation transfer structure of a three-dimensional drying device provided in the embodiment;

fig. 5 is a left side view of a circulation transfer structure of a three-dimensional drying device provided in the embodiment;

fig. 6 is a right side view of a circulation transfer structure of a three-dimensional drying device provided in the embodiment;

fig. 7 is a schematic structural diagram of a frame transfer mechanism of the three-dimensional drying apparatus according to the embodiment;

fig. 8 is a schematic side view of a frame transfer mechanism of a three-dimensional drying apparatus according to an embodiment.

Reference numerals:

name (R)	Numbering	Name (R)	Numbering	Name (R)	Numbering
						Heating frame	1	Lifting and stacking transmission mechanism	22	Push plate	236
Frame layer	11	Bearing angle iron	221	Engaging part	236a
						Thermal insulation cotton layer	12	Lifting motor	222	Gear wheel	237
Input pipeline	13	Lifting transmission rod	223	Descending stacking transmission mechanism	24
						Output pipeline	14	Net frame transfer mechanism	23	Descending motor	241
Circulation transmission structure	2	Load transferring motor	231	Descending transmission rod	242
						Upper net feeding transmission mechanism	21	A first driving shaft	232	Upper-layer net-outlet transmission mechanism	25
Network-entering motor	211	Second driving shaft	233	Outgoing network motor	251
						First active transmission rod	212	Load shifting chain	234	Second active transmission rod	252
First annular chain transmission mechanism	213	Guide shaft	235	Second annular chain transmission mechanism	253

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

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

Example (b):

referring to fig. 1 to 8, the present embodiment provides a three-dimensional drying apparatus, which is applied to drying a pre-printing treatment liquid for a ready-made clothes printing fabric on a screen frame carrier, and includes:

the heating device comprises a heating frame body 1 and a circulating transmission structure 2 arranged in the heating frame body 1;

the circulating transmission structure 2 comprises an upper-layer net inlet transmission mechanism 21, a rising stacking transmission mechanism 22, a net frame transfer mechanism 23, a falling stacking transmission mechanism 24 and an upper-layer net outlet transmission mechanism 25;

the upper-layer net inlet transmission mechanism 21 and the upper-layer net outlet transmission mechanism 25 are respectively arranged at two ends in the length direction in the heating frame body 1 and used for inputting and outputting the net frame carrier;

the ascending stacking transmission mechanism 22 is arranged at the upper end of the upper-layer net feeding transmission mechanism 21, and the descending stacking transmission mechanism 24 is arranged at the upper end of the upper-layer net discharging transmission mechanism 25;

the screen frame transfer mechanism 23 is connected with both the ascending stacking transmission mechanism 22 and the descending stacking transmission mechanism 24, and is arranged at the upper ends of the ascending stacking transmission mechanism 22 and the descending stacking transmission mechanism 24; so that the upper net feeding transmission mechanism 21, the ascending stacking transmission mechanism 22, the net frame transfer mechanism 23, the descending stacking transmission mechanism 24 and the upper net discharging transmission mechanism 25 are sequentially connected to form a zigzag structure;

in the heating frame body 1, the mesh frame carrier carrying the ready-made clothes printing fabric is moved in by the upper layer mesh feeding transmission mechanism 21, transferred to the mesh frame transfer mechanism 23 through the ascending stacking transmission mechanism 22, translated to the descending stacking transmission mechanism 24 through the mesh frame transfer mechanism 23, and moved out through the upper layer mesh discharging transmission mechanism 25 after being transferred downwards.

After the ready-made clothes printing fabric is treated by the printing pretreatment liquid, the ready-made clothes printing fabric can be printed only by drying. Because the water content in the printing pretreatment liquid is very high, the fabric can be fully dried only by drying at a high temperature of 30 minutes, and printing can be carried out.

The carrier screen frame is a carrier for placing and fixing the ready-made clothes printing fabric.

The heating housing 1 is an external heating device. The hot air flow can be input into the inner part to circulate the hot air flow in the inner part, so that the carrier net frame which moves circularly achieves the drying effect.

The upper-layer net feeding transmission mechanism 21, the ascending stacking transmission mechanism 22, the net frame transfer mechanism 23, the descending stacking transmission mechanism 24 and the upper-layer net discharging transmission mechanism 25 are sequentially connected to form a zigzag structure. The ascending stacking transmission mechanism 22 and the descending stacking transmission mechanism 24 are respectively used for ascending and descending the carrier net frame, and the net frame transfer mechanism 23 is used for horizontally moving the carrier net frame from left to right. The upper-layer net-in transmission mechanism 21 and the upper-layer net-out transmission mechanism 25 are used for being connected with other equipment, so that automatic input and output are realized, and automatic operation of drying and printing clothes is achieved.

In the embodiment, a three-dimensional drying device is provided, in the heating frame 1, a screen frame carrier carrying the ready-made clothes printing fabric is moved in by the upper layer screen feeding transmission mechanism 21, transferred to the screen frame transfer mechanism 23 by the ascending stacking transmission mechanism 22, translated to the descending stacking transmission mechanism 24 by the screen frame transfer mechanism 23, and moved out by the upper layer screen discharging transmission mechanism 25 after being transferred downwards. The utility model discloses an in heating framework 1, control each carrier net frame and circulate in step and remove, make the temperature that receives of every carrier net frame, the process of being heated and the mode of being heated keep unanimous basically, the time of being heated is invariable, very big having avoided because the temperature difference, whether it is even to be heated, the technological problem that external factors such as the residual temperature after the stop heating leads to, the colour difference scheduling problem that produces from this is avoided to utmost.

Preferably, the heating frame 1 is provided with an outer frame layer 11 and an insulating cotton layer 12 arranged in the frame layer 11; the heating frame 1 is provided with an input pipeline 13 for inputting hot air flow and an output pipeline 14 for flowing out hot air flow.

Above-mentioned, heating frame 1 includes inside heat preservation surface course, outside frame layer 11 for make the hot gas flow of inside input carry out the thermal radiation and keep apart, thereby keep inside high temperature environment, in order to reach better stoving effect.

Preferably, the upper-layer net inlet transmission mechanism 21 and the upper-layer net outlet transmission mechanism are arranged in parallel, and the input and output transmission directions are consistent.

The net feeding and the net discharging are arranged in parallel, for example, the net can be fed from the lower end of the left side and output from the lower end of the right side, so that the carrier net frame is in a polygonal moving track, and drying is realized.

Preferably, the upper-layer net feeding transmission mechanism 21 comprises a net feeding motor 211, a first driving transmission rod 212 connected with the net feeding motor 211, and two first annular chain transmission mechanisms 213 which are symmetrically and parallelly arranged and connected with the first driving transmission rod 212; the first endless chain transmission mechanism 213 can synchronously rotate under the rotational power output by the net feeding motor 211;

the upper-layer outgoing transmission mechanism 25 comprises an outgoing motor 251, a second driving transmission rod 252 connected with the outgoing motor 251, and two symmetrical and parallel second annular chain transmission mechanisms 253 connected with the second driving transmission rod 252; the second endless chain transmission mechanism 253 can synchronously rotate under the rotational power output by the net feeding motor 211.

The upper layer net feeding transmission mechanism 21 and the upper layer net discharging transmission mechanism 25 are correspondingly arranged, wherein the upper layer net feeding transmission mechanism is internally provided with the first annular chain transmission mechanism 213 which is formed by two parallel speed-multiplying chains and chain wheels which are powered by a net feeding motor 211, and the upper surfaces of the two speed-multiplying chains form a transmission plane for supporting the transmission of a net frame so as to facilitate the automatic advance of the net frame; the two speed-multiplying chains are both annular, and the inner sides of the speed-multiplying chains are provided with driving sprockets for driving the speed-multiplying chains; one end of the first driving transmission rod 212 is linked with a driving sprocket in one speed doubling chain, the other end of the driving transmission rod is connected with a driving sprocket in the other speed doubling chain and extends outwards to be connected with a motor, the driving transmission rod is driven to rotate by controlling the motor to drive the two driving sprockets to transmit, and the upper-layer net outlet transmission mechanism 25 is similar to the upper-layer net inlet transmission mechanism 21 in structure.

Preferably, the ascending stacking actuator 22 and the descending stacking actuator 24 are opposite in conveying direction of the frame carriers; wherein the content of the first and second substances,

the ascending stacking transmission mechanism 22 is used for conveying the screen frame carrier output by the upper-layer screen feeding transmission mechanism 21 to the screen frame transfer mechanism 23 from bottom to top;

the descending stacking transmission mechanism 24 is used for conveying the screen frame carrier output by the screen frame transfer mechanism 23 to the upper-layer screen outlet transmission mechanism 25 from top to bottom.

Preferably, each of the ascending stacking transmission mechanism 22 and the descending stacking transmission mechanism 24 includes 4 vertically and symmetrically arranged pulling and moving components, and a plurality of supporting angle irons 221 arranged on the pulling and moving components, so that in the ascending stacking transmission mechanism 22, the net frame carrier is lifted upwards to move by corresponding supporting angle irons 221 on the 4 pulling and moving components; and, in the descending stacking transmission mechanism 24, the screen frame carrier is lifted by corresponding supporting angle irons 221 on 4 traction moving components to move downwards.

The traction moving component can be a chain wheel connected with a motor and a chain wound on the two wheels, so that a mechanism rotating under the driving of the motor can be realized, and the ascending or descending of the bearing angle iron 221 can be driven.

Preferably, the supporting angle iron 221 is an L-shaped supporting angle iron 221;

each said supporting angle iron 221 is provided with said supporting angle iron 221 in other said traction movement assemblies corresponding thereto and in the same horizontal plane.

As described above, the plurality of support angle irons 221 are disposed on the towing movement assembly at a certain distance, so that when the 4 towing movement assemblies are in motion, each support angle iron 221 corresponds to and is parallel to the support angle iron 221 on the same horizontal plane on the other towing movement assemblies. Thereby, the smooth upward lifting of the carrier net frame can be realized.

In the above, the support angle 221 is L-shaped, so that the carrier screen frame can be fixed and lifted.

The lifting stacking transmission mechanism 22 comprises 4 double-layer chains and bearing angle irons 221, a plurality of parallel lifting L plates are locked on the two double-layer chains on each side, the lifting L plates on the two sides are correspondingly equal in height to form a lifting plane, the net frame is convenient to fix and lift, double-layer chain wheels for driving the double-layer chains are installed on the inner sides of the double-layer chains, a lifting driving transmission rod is arranged on each side, one end of the lifting driving transmission rod is connected with the double-layer chain wheel in one double-layer chain, the other end of the lifting driving transmission rod is connected with the double-layer chain wheel in the other double-layer chain wheel and extends out of a connection motor, and the lifting driving transmission rod is driven by a control.

Preferably, the lifting and stacking transmission mechanism 22 further comprises a lifting motor 222, and two lifting transmission rods 223 connected with the lifting motor 222,

the 4 traction moving assemblies are connected in pairs through a lifting transmission rod 223; so that under the driving of the lifting motor 222, based on the transmission of the lifting transmission rod 223, 4 traction moving components synchronously drive the bearing angle iron 221 to move.

The descending stacking transmission mechanism further comprises a descending motor 241, and two descending transmission rods 242 connected with the descending motor 241,

the 4 traction moving assemblies are connected in pairs through a descending transmission rod 242; so that under the driving of the descending motor 241, based on the transmission of the descending transmission rod 242, 4 of the traction moving components synchronously drive the supporting angle iron 221 to move.

Preferably, the frame transfer mechanism 23 includes a transfer motor 231, a first driving shaft 232 connected to the transfer motor 231 and disposed in a horizontal direction, and a second driving shaft 233 far away from the first driving shaft 232;

the first driving shaft 232 and the second driving shaft 233 are both provided with a gear 237, and a transfer chain 234 is sleeved on the gear 237 on the first driving shaft 232 and the gear 237 on the second driving shaft 233;

the frame transfer mechanism 23 is further provided with a guide shaft 235 which is perpendicular to the first driving shaft 232 and has a length matched with the distance between the first driving shaft 232 and the second driving shaft 233;

a push plate 236 for pushing the screen frame carrier in the horizontal direction is arranged on the guide shaft 235; the push plate 236 can move horizontally along the length direction of the guide shaft 235;

the pushing plate 236 is provided with an engaging portion 236a engageable with the transfer chain, so that the transfer chain 234 rotates along with the first driving shaft 232 and the second driving shaft 233 synchronously rotates under the driving of the transfer motor 231, and the transfer chain drives the pushing plate 236 engaged therewith to reciprocate along the guide shaft 235.

The transfer motor 231 can output rotational power in different directions, that is, forward and reverse rotation, and thus the chain can be rotated in a cycle within a certain distance. Therefore, the corresponding push plate 236 can be driven by the chain to move within a certain range to push the carrier screen frame and reset.

For example, the frame transfer mechanism 23 is composed of two parallel stainless steel chains cooperating with the transfer driving shaft to drive the push plate 236, the lower surfaces of the two stainless steel chains form a plane for supporting the fixed push plate 236 to move, and the directional axis of the push plate 236 is used to fix the moving direction and moving mode of the push plate 236, thereby preventing the push plate 236 from deflecting. The power mode is the same as that of the upper-layer net feeding conveying mechanism, and the driving shaft is driven by the motor to rotate to drive the chain to move, so that the push plate 236 pushes the net frame to advance.

Above, the motion mode of the drying apparatus provided by this embodiment is:

the carrier screen frame is conveyed into the upper layer screen feeding transmission mechanism 21 through the conveyor belt, the motor drives the driving rod to drive the chain to enable the upper layer screen feeding transmission mechanism 21 to move, the screen frame is driven to reach a preset position, the motor driving shaft of the ascending stacking transmission mechanism 22 drives the double-layer chain, the L plate connected with the chain drives the screen frame to ascend by a preset height, the movement is repeated until the screen frame ascends to the topmost end of the stack, the screen frame transferring mechanism 23 drives the motor driving shaft of the screen frame, the push plate 236 is pushed to make the linear movement on the guide shaft 235, the screen frame is pushed to move to the topmost layer of the descending stacking movement mechanism, the descending stacking movement mechanism descends by a preset height until the screen frame is lowered to the upper layer screen discharging movement mechanism, the screen frame is taken out through the upper layer screen discharging movement mechanism in the same principle, the. The net frame with the cloth taken down is brought back to the initial sheet laying working position through the lower layer net returning motion mechanism.

In the description herein, references to the description of the terms "one embodiment," "some embodiments," "an example," "a specific example," or "some examples" or the like mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is a more detailed description of the present invention that is presented in conjunction with specific embodiments, and it is not to be understood that the specific embodiments of the present invention are limited to these descriptions. To the utility model belongs to the technical field of ordinary technical personnel, do not deviate from the utility model discloses under the prerequisite of design, can also make a plurality of simple deductions or replacement.

Claims

1. The utility model provides a three-dimensional drying device, is applied to the stoving to locating the processing liquid before the printing of the ready-made clothe printing surface fabric on the screen frame carrier, its characterized in that includes:

2. The stereoscopic drying device according to claim 1, wherein the heating frame body is provided with an outer frame body layer and an insulation cotton layer arranged in the frame body layer; the heating frame body is provided with an input pipeline for inputting hot air flow and an output pipeline for flowing out of the hot air flow.

3. The stereoscopic drying apparatus according to claim 1, wherein the upper layer net-in transmission mechanism and the upper layer net-out transmission mechanism are arranged in parallel, and the input and output transmission directions are consistent.

4. The stereoscopic drying apparatus of claim 3,

the upper-layer net feeding transmission mechanism comprises a net feeding motor, a first active transmission rod connected with the net feeding motor, and two first annular chain transmission mechanisms which are symmetrically and parallelly arranged and connected with the first active transmission rod; the first annular chain transmission mechanism can synchronously rotate under the rotating power output by the net feeding motor;

5. The stereoscopic drying apparatus of claim 1,

the ascending stacking transmission mechanism and the descending stacking transmission mechanism are opposite to the conveying direction of the screen frame carrier; wherein the content of the first and second substances,

6. The stereoscopic drying apparatus as claimed in claim 5, wherein the ascending and stacking transmission mechanism and the descending and stacking transmission mechanism each comprise 4 vertically and symmetrically arranged pulling and moving components, and a plurality of supporting angle irons arranged on the pulling and moving components, so that in the ascending and stacking transmission mechanism, the net frame carrier is lifted and moved upwards through the corresponding supporting angle irons on the 4 pulling and moving components; and lifting the screen frame carrier to move downwards in the descending stacking transmission mechanism through corresponding bearing angle irons on 4 traction moving components.

7. The stereoscopic drying apparatus of claim 6,

the bearing angle iron is L-shaped bearing angle iron;

8. The stereoscopic drying apparatus of claim 7,

the lifting stacking transmission mechanism also comprises a lifting motor and two lifting transmission rods connected with the lifting motor,

9. The stereoscopic drying apparatus of claim 1,

the screen frame transfer mechanism comprises a transfer motor, a first driving shaft and a second driving shaft, wherein the first driving shaft is connected with the transfer motor and arranged in the horizontal direction, and the second driving shaft is far away from the first driving shaft;