Disclosure of Invention
The invention aims to provide a medical non-woven fabric dressing and a preparation method thereof, and aims to solve the problem that a single person is inconvenient to tighten when attaching plaster.
In order to achieve the above object, the present invention provides the following technical solutions: the utility model provides a medical non-woven fabrics dressing and preparation method thereof, includes quick-open composite cloth, and it includes two non-woven fabrics layers of laminating each other, two be the linear array between the non-woven fabrics layer and be provided with a plurality of ropes that drag, drag rope first end and two non-woven fabrics layer fixed connection, drag the rope and receive the tractive stretch out the non-woven fabrics layer to order about two non-woven fabrics layer shrink.
Preferably, an elastic layer is arranged between the non-woven fabric layers in a linear array, a fixed frame is arranged at the first end of the dragging rope, and the non-woven fabric layers are arranged on the fixed frame.
The preparation method of the medical non-woven fabric dressing specifically comprises the following steps:
S01, sequentially stacking the non-woven fabric layer, the fixed frame and the non-woven fabric layer on a positioning groove of the conveyor belt through a mechanical arm;
s02, carrying along with a conveyor belt, wherein the first ends of the two non-woven fabric layers are stretched and tensioned;
s03, fixing the first end of the quick-stretching composite cloth by hot pressing, and conveying air between the two non-woven fabric layers to comb the dragging rope;
S04, carrying out hot pressing and fixing along the rotary meshing column along with the conveying belt to form the quick-opening composite cloth.
Preferably, the carding mechanism is arranged on the rotary meshing column and comprises a rotating wheel rotating along with the rotary meshing column in a variable speed manner, a plurality of elastic air needles are arranged on the rotating wheel in a circumferential array, and the elastic air needles are penetrated into the non-woven fabric layer along with the rotation of the rotating wheel and are in air transmission.
Preferably, the hot-press driving mechanism further comprises a fixed disc coaxially arranged with the rotary meshing column, and the rotating wheel is rotatably connected to the rotary meshing column and is attached to the fixed disc, so that the rotating wheel rotates while revolving along with the rotary meshing column.
Preferably, the rotary meshing column is provided with a hot pressing bar, and the hot pressing bar is provided with a hot flow channel which is movably communicated with the elastic air needle so that the elastic air needle outputs hot flow.
Preferably, the device further comprises a gas transmission unit, wherein the gas transmission unit comprises a gas transmission barrel which is coaxially arranged with the rotary meshing column, a rotary wave plate and a gas transmission pipe are arranged on the gas transmission barrel, the gas transmission pipe is fixedly communicated with the heat flow channel, and the rotary wave plate rotates along with the rotary meshing column to continuously transmit gas to the heat flow channel.
Preferably, the rotary meshing column is provided with a hot pressing bar and a tensioning mechanism, the tensioning mechanism comprises a sliding column which is symmetrically and obliquely movably arranged, and the sliding column is mutually far away from each other along with the rotation of the rotary meshing column so as to stretch the non-woven fabric layer.
Preferably, the device further comprises a clockwise supporting mechanism, wherein the clockwise supporting mechanism comprises an arc-shaped plate which is rotationally connected to the rotary meshing column, clockwise meshing grooves are formed in the arc-shaped plate in a linear array mode, the two ends of the clockwise meshing grooves are respectively provided with a large end and a small end, and the arc-shaped plate overturns along the rotary meshing column to drive the large end and the small end to be sequentially attached to the dragging rope.
Preferably, the arc plate is fixedly communicated with an elastic ventilation column, and the elastic ventilation column is communicated with the heat flow channel along with the overturning of the arc plate so as to thermally mould the dragging rope.
In the technical scheme, the medical non-woven fabric dressing and the preparation method thereof provided by the invention have the following beneficial effects: when laminating needs tensile position, laminate the non-woven fabrics layer on the position and pull the rope, the non-woven fabrics layer can fold and shrink this moment to pull the rope and pull the non-woven fabrics layer and tighten up and give the effect of wound position traction tension through dragging, need not both hands can realize tensioning effect, and when laminating the position that needs movable such as joint, can pull earlier and pull the rope and tighten up the non-woven fabrics layer, then folding non-woven fabrics layer can extend along with the joint activity, guarantees the laminating.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present disclosure. It will be apparent that the described embodiments are some, but not all, of the embodiments of the present disclosure. All other embodiments, which can be made by one of ordinary skill in the art without the need for inventive faculty, are within the scope of the present disclosure, based on the described embodiments of the present disclosure.
Example 1
As shown in fig. 1, a medical non-woven fabric dressing comprises a rapid-stretching composite fabric 6, wherein the rapid-stretching composite fabric comprises two non-woven fabric layers 61 which are mutually adhered, a plurality of dragging ropes 62 are arranged between the two non-woven fabric layers 61 in a linear array, first ends of the dragging ropes 62 are fixedly connected with the two non-woven fabric layers 61, and the dragging ropes 62 stretch out of the non-woven fabric layers 61 by traction to drive the two non-woven fabric layers 61 to shrink.
Specifically, the second ends (refer to fig. 1, the right end is the first end, and the left end) of the plurality of drag ropes 62 are provided with drag parts, and the drag parts extend out of one of the non-woven fabric layers 61, so that a user can drag the plurality of drag ropes 62 for use, and the other non-woven fabric layer 61 is provided with a self-adhesive layer and a plaster layer, so that the external application treatment can be performed while the injured part is attached.
In the above technical scheme, when laminating needs tensile position, laminate non-woven fabrics layer 61 on the position of needs external application treatment and pull and drag rope 62, non-woven fabrics layer 61 can fold shrink this moment, with pull rope 62 pull non-woven fabrics layer 61 tighten up and give the effect that the wound position was pulled tightly, can realize tensioning effect with two hands not, make things convenient for single operation to use, and when laminating the position that needs the activity such as joint, can pull earlier and drag rope 62 tighten up non-woven fabrics layer 61, then folding non-woven fabrics layer 61 can extend along with the joint activity, when guaranteeing laminating wound position, can not restrict the activity of joint.
As a preferred embodiment of the present invention, the elastic layers 611 are disposed in a linear array between the non-woven fabric layers 61, the fixing frame 621 is disposed at the first end of the drag rope 62, and the non-woven fabric layers 61 are disposed on the fixing frame 621.
Specifically, the elastic layer 611 can extend or contract when the drag ropes 62 are pulled, the fixing frame 621 half-wraps the non-woven fabric layer 61, covers 60% of the side length of the non-woven fabric layer 61, the fixing frame 621 is made of pp plastic and can deform along with deformation of the elastic layer 611, and the fixing frame 621 is used for connecting a plurality of drag ropes 62, so that the manipulator can move conveniently.
Example two
As shown in fig. 1, the preparation method of the medical non-woven fabric dressing specifically comprises the following steps:
s01, sequentially stacking the non-woven fabric layer 61, the fixing frame 621 and the non-woven fabric layer 61 on the positioning groove 12 of the conveyor belt 1 by a mechanical arm;
S02, carrying along with the conveyor belt 1, stretching and tensioning the first ends (taking fig. 1 as a reference and the first end as the right end) of the two non-woven fabric layers 61 in opposite directions along the central axis of the conveyor belt 1 so as to fix the two non-woven fabric layers 61 and the fixing frame 621, and avoiding the non-woven fabric layers 61 and the fixing frame 621 from being deformed in a separation position in the hot pressing process;
S03, fixing the first end of the quick-stretching composite cloth 6 by hot pressing through a hot pressing bar 22, continuously rolling along with the rotary meshing column 21, conveying air between the two non-woven fabric layers 61 to prop the two non-woven fabric layers 61 open, carding the twisted dragging ropes 62 into a vertical state through air flow, and avoiding twisting the dragging ropes 62 in the hot pressing process;
s04, carrying along with the conveyor belt 1, and carrying out hot pressing and fixing along with the rotary meshing column 21 to form the quick-opening composite cloth 6.
As shown in fig. 1 to 8, the carding mechanism 3 is arranged on the rotary meshing column 21, the carding mechanism 3 comprises a rotating wheel 31 rotating along with the rotary meshing column 21 in a variable speed, the rotating wheel 31 is provided with a plurality of elastic air needles 321 in a circumferential array, and the elastic air needles 321 are penetrated into the non-woven fabric layer 61 along with the rotation of the rotating wheel 31 and are used for air transmission.
Specifically, the positioning groove 12 is formed in the conveyor belt 1, the engaging groove 11 is symmetrically formed in the conveyor belt 1 along the positioning groove 12, the rotary engaging columns 21 are symmetrically formed along the conveyor belt 1, the engaging edges 211 corresponding to the engaging grooves 11 one by one are formed in the rotary engaging columns 21, the engaging edges 211 and the engaging grooves 11 are used for synchronizing the conveyor belt 1 and the rotary engaging columns 21, accuracy in engaging hot pressing is guaranteed, the laminating elastic plate 121 is arranged in the positioning groove 12 and used for placing the quick-stretching composite cloth 6, normal use of the two rotary engaging columns 21 is not affected, and the rotating wheel 31 extends out of the rotary engaging columns 21 for a preset distance (the preset distance is the diameter of the elastic air needle 321)
+2-2.5 Mm), the rotating wheel 31 is provided with a rotating groove 311, the rotating groove 311 is rotationally connected with a ventilation rotating column 32, a plurality of elastic air needles 321 are fixedly communicated with the ventilation rotating column 32, the elastic air needles 321 are provided with bending parts, the rotating wheel 31 can bend and move, and the rotating speed of the rotating wheel 31 is faster than that of the rotary meshing column 21. When in use, the mechanical arm places the non-woven fabric layer 61 and the fixing frame 621 on the positioning groove 12, then the rotary meshing column 21 performs hot pressing fixing on the first end of the non-woven fabric layer 61, after the first end of the non-woven fabric layer 61 is hot pressed, the elastic air needle 321 rotates to penetrate between the two non-woven fabric layers 61, and performs air transmission to separate the two non-woven fabric layers 61 and blow the dragging rope 62 straight, so that subsequent hot pressing is performed, and the elastic air needle 321 can bend along the bending part along with the continuous rotation of the rotating wheel 31 so as to separate from the non-woven fabric layers 61.
As an embodiment of the present invention, the hot press driving mechanism 2 further comprises a fixed disk 212 coaxially disposed with the rotary engagement post 21, and the rotating wheel 31 is rotatably connected to the rotary engagement post 21 and is fitted to the fixed disk 212 so that the rotating wheel 31 rotates while revolving with the rotary engagement post 21.
Specifically, the rotary meshing column 21 and the fixed disk 212 are both disposed on a frame (a frame that can be made of a profile, or a frame that can be made of cast iron) and the fixed disk 212 is fixed, the rotary meshing column 21 can rotate, an extended friction layer is disposed on the rotating wheel 31, the friction layer is always attached to the fixed disk 212, when the rotary meshing column 21 rotates, the rotating wheel 31 revolves around the rotary meshing column 21 and rotates along with the fixed disk 212 due to friction of the rotating wheel 21, the rotating speed of the rotating wheel 31 is faster than that of the rotary meshing column 21 due to the diameter of the friction layer being smaller than that of the rotary meshing column 21, so that the elastic air needle 321 pierces the nonwoven fabric layer 61, and an elastic member for resetting is disposed between the rotating groove 311 and the ventilation rotating column 32.
When the air vent rotary column is used, the mechanical arm places the non-woven fabric layer 61 and the fixing frame 621 on the positioning groove 12, then the rotary meshing column 21 rotates to perform hot pressing fixing on the first end of the non-woven fabric layer 61, after the first end of the non-woven fabric layer 61 is hot pressed, the elastic air needle 321 is rotated to penetrate between the two non-woven fabric layers 61 due to the rotation of the rotating wheel 31, meanwhile, the air vent rotary column 32 rotates and performs air transmission, so that the dragging rope 62 is blown straight while the two non-woven fabric layers 61 are separated, so that subsequent hot pressing is performed, the elastic air needle 321 is bent along the bending part along with the continuous rotation of the rotating wheel 31 to separate from the non-woven fabric layer 61, and the air vent rotary column 32 resets to stop ventilation.
As a preferred embodiment of the present invention, the rotary engagement post 21 is provided with a heat pressing bar 22, and the heat pressing bar 22 is provided with a heat flow channel 221 movably connected with the elastic air needle 321, so that the elastic air needle 321 outputs heat flow.
Specifically, the hot pressing strip 22 is arc-shaped, the shape of the transfer surface is the same as that of the fixing frame 621, the heat flow channel 221 is fixedly communicated with the air charging unit (the air charging unit can be an air pump or an air pipe), so that the heat flow channel 221 can output heat flow when being communicated with other channels, the rotating wheel 31 is movably provided with the communicated air strip 323, the communicated air strip 323 is fixedly communicated with the heat flow channel 221, when the rotating wheel 31 rotates, the corresponding ventilation rotary column 32 on the elastic air needle 321 penetrating into the non-woven fabric layer 61 can enter the communicated air strip 323 to be communicated with the heat flow channel 221, the air channel 322 is provided with the air channel 322, and the air channel 322 is misplaced with the rotary groove 311 only when the ventilation rotary column 32 rotates, so that the elastic air needle 321 outputs heat flow, and the heat flow can soften the non-woven fabric layer 61 and drag rope 62 to play a role in assisting in plasticity.
When in use, the manipulator places the non-woven fabric layer 61 and the fixing frame 621 on the positioning groove 12, then the rotary meshing column 21 rotates to perform hot pressing fixing on the first end of the non-woven fabric layer 61, after the first end of the non-woven fabric layer 61 is hot pressed, the elastic air needle 321 is rotated to penetrate between the two non-woven fabric layers 61 due to the rotation of the rotating wheel 31, meanwhile, the ventilation rotating column 32 is pulled to rotate to enable the air passage 322 to be misplaced with the rotating groove 311 to be communicated with the heat flow channel 221 and carry out air transmission, the dragging rope 62 can be blown straight while the two non-woven fabric layers 61 can be separated, so that the follow-up hot pressing is performed, the elastic air needle 321 can be bent along the bending part along with the continued rotation of the rotating wheel 31 to separate from the non-woven fabric layer 61, and the ventilation rotating column 32 returns to the position to break the communication with the heat flow channel 221 to stop ventilation.
As a preferred embodiment of the present invention, the present invention further comprises a gas delivery unit 5, which includes a gas delivery barrel 51 coaxially disposed with the rotary engagement post 21, wherein a rotary wave plate 511 and a gas delivery pipe 52 are disposed on the gas delivery barrel 51, the gas delivery pipe 52 is fixedly communicated with the heat flow channel 221, and the rotary wave plate 511 continuously delivers gas to the heat flow channel 221 along with the rotation of the rotary engagement post 21.
Specifically, the air pipe 52 is provided with an air ring 521, the air ring 521 is movably connected to the air conveying barrel 51, the air conveying barrel 51 is rotatably connected to the rotary meshing column 21, a meshing wheel is arranged between the air conveying barrel 51 and the fixed disc 212, and when the rotary meshing column 21 rotates, the meshing wheel rubs the fixed disc 212 to drive the air conveying barrel 51 to rotate, so that the rotary wave plate 511 inputs air flow into the heat flow channel 221 along the air ring 521 and the air pipe 52, air pressure in the heat flow channel 221 is kept, and meanwhile, the fixed disc 212 drives the air conveying barrel to reduce the communication of an additional air charging unit.
When in use, the mechanical arm places the non-woven fabric layer 61 and the fixing frame 621 on the positioning groove 12, then the rotary meshing column 21 rotates to perform hot pressing fixing on the first end of the non-woven fabric layer 61, the rotary wave plate 511 continuously rotates to input air flow into the heat flow channel 221 for heating, after the first end of the non-woven fabric layer 61 is hot pressed, the elastic air needle 321 is rotated to penetrate between the two non-woven fabric layers 61 due to the rotation of the rotating wheel 31, meanwhile, the ventilation rotating column 32 is pulled to rotate to enable the air channel 322 to be misplaced with the rotating groove 311 to be communicated with the heat flow channel 221, air transmission is performed, the two non-woven fabric layers 61 can be separated, meanwhile, the dragging rope 62 is blown straight, so that subsequent hot pressing is performed, the elastic air needle 321 can be bent along the bending part to be separated from the non-woven fabric layer 61 due to the rotation of the rotating wheel 31, and the ventilation rotating column 32 returns to the position to break communication with the heat flow channel 221 to stop ventilation.
As a preferred embodiment provided by the invention, the hot press bar 22 and the tensioning mechanism 7 are arranged on the rotary meshing column 21, and the tensioning mechanism 7 comprises symmetrically and obliquely movably arranged sliding columns 72, and the sliding columns 72 rotate along with the rotary meshing column 21 to be far away from each other so as to pull the non-woven fabric layer 61 to be tensioned.
Specifically, the tensioning mechanism 7 further includes a fixing block 71 disposed at two ends of the heat pressing strip 22, an inclined slideway is disposed on the fixing block 71, the sliding column 72 is slidably connected in the inclined slideway, a spring 73 is disposed between the fixing block 71 and the inclined slideway, the spring 73 pushes the sliding column 72 to extend out of the inclined slideway, before the heat pressing strip 22 rotates along with the rotation of the rotary meshing column 21 to heat and press the first end of the composite cloth 6, the sliding column 72 will first contact with the non-woven fabric layer 61, then along with the rotation of the rotary meshing column 21, the sliding column 72 will push the spring 73 to compress and retract along the inclined slideway, so that two ends of the sliding column 72 are far away from each other to stretch the first end of the non-woven fabric layer 61, and then the heat pressing strip 22 heat presses the first end of the non-woven fabric layer 61, so as to play a pre-fixing effect, so as to avoid dislocation or separation of the non-woven fabric layer 61 in the heat pressing process.
When in use, the manipulator places the non-woven fabric layer 61 and the fixing frame 621 on the positioning groove 12, then the rotary meshing column 21 rotates to heat and press the first end of the non-woven fabric layer 61, the two ends of the sliding column 72 are firstly attached to the non-woven fabric layer 61, the first end of the non-woven fabric layer 61 is tensioned along with the rotation and separated from each other, then the first end of the non-woven fabric layer 61 is heated, the rotary wave plate 511 continuously rotates to input air flow into the heat flow channel 221 for heating, after the first end of the non-woven fabric layer 61 is heat-pressed, the elastic air needle 321 is rotated to penetrate between the two non-woven fabric layers 61 due to the rotation of the rotating wheel 31, meanwhile, the air passage column 32 is pulled and rotated to enable the air passage 322 to be misplaced with the rotary groove 311 for communicating the heat flow channel 221, and air transmission can be carried out, the dragging rope 62 is blown straight while the two non-woven fabric layers 61 can be separated for subsequent heat pressing, the elastic air needle 321 can be bent along the bending part along with the bending part of the rotating wheel 31 continuously, the elastic air needle 321 is separated from the non-woven fabric layer 61, and the communication with the heat flow channel 221 is stopped due to the restoration position of the air passage column 32.
As an embodiment of the present invention, the present invention further includes a clockwise supporting mechanism 4, which includes an arc plate 42 rotatably connected to the rotary meshing column 21, a clockwise engaging groove 422 is formed on the arc plate 42 in a linear array, two ends of the clockwise engaging groove 422 are respectively provided with a large end and a small end, and the arc plate 42 is turned over along the rotary meshing column 21 to drive the large end and the small end to sequentially attach to the drag rope 62.
Specifically, the forward support mechanism 4 further includes a base frame 41 disposed on the rotary meshing column 21, a first end (refer to fig. 7, and a right end) of the arc plate 42 is rotatably connected to the base frame 41, an arc transition is formed between a large end and a small end on the forward engagement slot 422, the large end is located at the first end of the arc plate 42, when the arc plate 42 is not limited, the small end is far away from the base frame 41 and is in a pop-up state, when the rotary meshing column 21 is hot-pressed, the arc plate 42 can be attached to the non-woven fabric layer 61 before the base frame 41 (or the hot pressing strip 22), and the drag rope 62 which is blown straight by the elastic air needle 321 can be further limited along the forward engagement slot 422, so that the drag rope 62 is kept vertical from beginning to end as much as possible, and waste products caused by bending of the drag rope 62 are reduced.
When in use, the non-woven fabric layer 61 and the fixing frame 621 are placed on the positioning groove 12 by the manipulator, then the rotation of the rotary meshing column 21 is performed to heat and press the first end of the non-woven fabric layer 61, the two ends of the sliding column 72 are firstly attached to the non-woven fabric layer 61, the first end of the non-woven fabric layer 61 is tensioned along with the rotation and kept away from each other, then the first end of the non-woven fabric layer 61 is heated, the rotary wave plate 511 continuously rotates to input air flow into the heat flow channel 221 for heating, after the first end of the non-woven fabric layer 61 is heated and pressed, the elastic air needle 321 is rotated to penetrate between the two non-woven fabric layers 61 due to the rotation of the rotary wheel 31, meanwhile, the air passage column 32 is pulled and rotated to enable the air passage 322 to be staggered with the rotary groove 311 to be communicated with the heat flow channel 221, and air transmission can be performed, the two non-woven fabric layers 61 can be separated and simultaneously blown straight by the pulling rope 62 so as to be heated and pressed subsequently, the elastic air needle 321 can be folded along the folded part to break away from the non-woven fabric layer 61, the recovery position of the air passage 32 is disconnected from being communicated with the heat flow channel 221, and stopped along with the rotation of the non-woven fabric layer 61, the rotation of the rotary meshing column 21 is continuously rotated along with the rotation meshing column 31 to keep rotating, and the rotation of the elastic air needle 321, and kept along with the air passage along with the heat and pulled along with the curved arc line 422, and bonded with the curved plate 422, and bonded along with the air line 422.
As the best embodiment provided by the invention, the arc plate 42 is fixedly communicated with the elastic ventilation column 421, and the elastic ventilation column 421 is communicated with the heat flow channel 221 along with the turnover of the arc plate 42 so as to thermoplastic the dragging rope 62.
Specifically, the elastic ventilation column 421 is fixedly connected with the plurality of downstream grooves 422, the elastic ventilation column 421 comprises a hollow pipeline and an elastic piece sleeved on the pipeline, the elastic piece is arranged between the base frame 41 and the arc plate 42, before the arc plate 42 is driven by the elastic piece to be in a pop-up state without being attached to the non-woven fabric layer 61, the small end of the arc plate 42 is far away from the base frame 41, a vent pipe is arranged on the heat flow channel 221, a unidirectional pulling plate is arranged on the vent pipe, after the arc plate 42 rotates to enter the base frame 41, the pipeline can be inserted into the vent pipe and overturns the unidirectional pulling plate to be communicated with the heat flow channel 221, at the moment, heat flow can thermoplastic the non-woven fabric along the downstream grooves 422, so that the shape of the non-woven fabric layer 61 is changed, the dragging rope 62 is fixed, displacement and deflection of the dragging rope 62 during subsequent transportation are avoided, and compared with the fact that the thermal compression energy is fixed, the thermal compression energy is also realized through forced external force, and normal use of the dragging rope 62 is not affected.
When in use, the manipulator places the non-woven fabric layer 61 and the fixed frame 621 on the positioning groove 12, then, when the rotary meshing column 21 rotates to thermally press the first end of the non-woven fabric layer 61, the two ends of the sliding column 72 can be attached to the non-woven fabric layer 61 at first, the first end of the non-woven fabric layer 61 is tensioned along with rotating and keeping away from each other, then, thermally pressing the first end of the non-woven fabric layer 61 is carried out, the rotary wave plate 511 continuously rotates to input air flow into the heat flow channel 221 for heating, after the first end of the non-woven fabric layer 61 thermally presses, the elastic air needle 321 is rotationally penetrated between the two non-woven fabric layers 61 due to the rotation of the rotating wheel 31, meanwhile, the air channel 322 and the rotary groove 311 are misplaced by pulling and rotating to enable the air channel 322 to be communicated with the heat flow channel 221, and the air channel 62 can be blown straight along with the rotary groove 311 when the two non-woven fabric layers 61 are separated, so that the subsequent thermal pressing is carried out, the elastic air needle 321 can be continuously rotated along with the bending part bending along with the rotating wheel 31 to break away from the non-woven fabric layer 61, the communication with the heat flow channel 221 is stopped, the communication between the elastic air needle 321 is cut off along with the connection of the non-woven fabric layer 21, the rotation meshing column 21 is continuously rotates along with the rotation of the rotating meshing column 31 to keep rotating the elastic air needle 321, the elastic air needle 321 rotates along with the thermal compression layer 61, the thermal compression line is completely rotates along with the thermal compression plate 422, the thermal compression plate 422 is completely, and the thermal compression plate 422 is completely rotates along with the thermal compression plate 422, and the thermal compression plate is completely bonded along with thermal compression line is completely, and the thermal compression plate 422 is completely, and the thermal compression line is completely, and the thermal plate is completely, and the thermal-bonded, when the thermal plate is completely, and the thermal plate and has high thermal and has.
While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the invention, which is defined by the appended claims.