JPH0552266B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a backing device for forming a backing material such as rubber on the back side of a base fabric of an automobile mat.

(Prior Art) Conventionally, as a bucking device for automobile mats, one disclosed in Japanese Patent Publication No. 37047/1983 has been proposed. As shown in FIGS. 14 and 15, a plurality of carts 5, each having a mold 2 attached to the upper surface and a heating device 3 attached to the lower portion, are placed on an annular track 4. 4, and is provided with a plastisol supply device 6, a pressurizing device 7, and a cooling device 8 at predetermined locations along the track 4, respectively.

In this car mat bucking device, the plastisol supplied into the mold 2 by the plastisol supply device 6 is heated by the heating device 3 provided at the bottom of the trolley 5 to semi-gel, and then fibers are added to the upper surface of the plastisol. The fiber mat 9 is placed and cooled by a cooling device 8 so that the fiber mat 9 is not exposed to heat, and the plastisol in the mold 2 is gelled.

(Problems to be Solved by the Invention) However, in this automobile mat bucking device, a plastisol supply device, a pressurizing device, and a cooling device are respectively provided at predetermined locations along the track, and the bogie is moved along the track. Although bucking is now performed by intermittent movement of the fiber mat, an operator must place the fiber mat on the plastisol and remove the fiber mat after bucking is completed. In particular, placing the fiber mat on the plastisol required great care and was an extremely complicated operation.

In addition, in the case of the conventional car mat bucking device, each truck must be moved by a worker, and it is very troublesome to move each truck to a predetermined location in a fixed amount of time, and the moving time of the truck is limited. If the process is delayed, the fiber mat and plastisol may not be fully welded and integrated due to insufficient pressure, or the plastisol may not gel due to insufficient heating, which may cause problems such as defective products. It was hot.

The present invention has been made in view of these problems, and it is an object of the present invention to provide an automobile mat backing device that can eliminate the work of attaching and removing fiber mats and can always produce uniform products. .

(Means for Solving the Problems) That is, the present invention provides a rotary drive table on which a plurality of molds are replaceably assembled, a resin coating device for applying resin onto the molds, and a resin coating device for applying resin onto the molds. a deaeration device that fills the mold into the mold; a mold heating device installed at the bottom of the rotary drive table; A mat bucking device for automobiles, comprising a fiber mat supply device, a mold cooling device provided at the bottom of a rotary drive table, and a removal device for peeling the fiber mat backed by resin from the mold. It is.

(Function of the Invention) Therefore, in the automobile mat bucking device of the present invention, supplying and removing the fiber mat, supplying the synthetic resin, heating and cooling the mold, and moving the mold are all performed by the device. Since this is done by mechanical operation, uniform products can always be produced.

In addition, in the automobile mat bucking device of the present invention, the fiber mat is supplied, removed,
Since the supply of synthetic resin, the heating and cooling of the mold, the movement of the mold, etc. are all performed by mechanical operations of the device, the workload of the operator can be significantly reduced.

(Example) The present invention will be explained in detail below with reference to the drawings.

FIG. 1 is a plan view showing the entire backing device for an automobile mat according to the present invention.

As shown in FIG. 1, a donut-shaped rotary drive table 20 on which a mold 12 is assembled is provided at the center of the bucking device 11, and a mold heating device 30 and a mold cooling device are provided at the bottom of this rotary drive table 20. 50, a resin coating device 70 on the outer peripheral edge;
Various devices such as a deaerator 90, a fiber mat supply device 110, a mold changing device 140, and a removing device 160 are provided.

This bucking device 11 can be divided into 15 zones in terms of function. That is, if the position of the resin coating device 70 provided on the outer peripheral edge of the rotary drive table 20 is defined as the first zone,
Along the rotational direction of the rotary drive table 20, the second zone has a mold heating device 30 at the bottom of the rotary drive table 20 and the deaerator at the outer peripheral edge, and the third to sixth zones have a mold heating device 30 at the bottom of the rotary drive table 20, and a deaerator at the outer peripheral edge. A mold heating device 30 is installed in the zone, and a rotary drive table 20 is installed in the seventh zone.
A mold heating device 30 is installed at the bottom of the rotary drive table 20, a fiber mat supply device 110 is installed at the outer peripheral edge, and a mold heating device 30 is installed at the bottom of the rotary drive table 20 in the 8th to 12th zones.
The 13th zone has a mold cooling device 50 at the bottom of the rotary drive table 20, the 14th zone has a mold cooling device 50 at the bottom of the rotary drive table 20, the mold changing device 140 at the outer peripheral edge, and the 15th zone has a mold cooling device 50 at the bottom of the rotary drive table 20. In each zone, removal devices 160 are sequentially provided on the outer peripheral edge of the rotary drive table 20.

As shown in FIG. 1, FIG. 2, FIG. 7, and FIG. 10, the rotary drive table 20 is a donut-shaped rotary disk that is installed on a concrete foundation and has wheels 21 at the upper end. shaped support stand 22
It is installed astride and rotatably supported. The rotary drive table 20 is provided with a
The DC servo motor 23 rotates intermittently, and this rotation is transmitted to the pulley 25 via the transmission 24. This pulley 25 comes into contact with the side of the rotary drive table 20, and the rotary drive table 20 is rotated by the pulley 25. It rotates intermittently in the opposite direction. In the case of this embodiment, the rotary drive table 20 stops rotating for 30 seconds every time it rotates approximately 24 degrees, and stops 15 times during one rotation of the rotary drive table 20. Fifteen mounting frames 26 for mounting the molds 12 are formed at equal intervals on the upper surface of the rotary drive table 20. A hole 27 slightly smaller than the mold 12 is formed in the assembly frame 26 . The mold 12, which is replaceably assembled on the top surface of the rotary drive table 20, has a diameter of 890 mm.
It is a plate formed with external dimensions of x670mm x 10mm, and is formed to match the size of an automobile mat. There are various types of molds 12 depending on the size of the automobile mat, and the molds 12 are replaceably assembled into the assembly frame 26 as required. Therefore, in this embodiment, 15 molds can be assembled into the apparatus, and up to 15 types of automobile mats can be manufactured. A mold heating device that heats the mold on the concrete base and a mold cooling device that cools the mold are provided below the rotary drive table independently of the rotary drive table.

As shown in FIGS. 1 to 6, a mold heating device 30
is the first buckling device 11 for automobile mats.
It is provided at the lower part of the rotary drive table 20 of each of the ~12 zones. This mold heating device 30 includes a frame 31 fixed on a concrete base and a gas burner 3 provided within this frame 31.
It is composed of 2. In this embodiment, 12 mold heating devices 30 are arranged at predetermined positions below the rotary drive table 20, and each mold heating device 30
is set so that the temperature of the mold 12 is approximately 180°C. Further, as the gas burner 32, a gas infrared burner type and a gas pipe burner type are used. A duct 35 is disposed between each of the mold heating devices 30 to which a firing blower and an exhaust fan are respectively attached.

The mold 12 in the assembly frame 26 of the rotary drive table 20 is directly heated from below the table 20.

The rotary drive table 20 is provided with a mold cooling device 50 at the bottom, similar to the mold heating device.

The mold cooling device 50 is installed in the 13th zone and the 14th zone of the automobile mat bucking device 11, respectively, and is connected to a cylinder 54 fixed to a concrete foundation, a water tank 52, and It is comprised of shower nozzles 53 protruding from three locations within a water tank 52. The water tank 52 is formed into a box shape and is supported by four pillars 51.
The tip of a shaft 55 of a cylinder 54 fixed on a concrete foundation is attached to the bottom of this water tank 52, and as the cylinder 54 expands and contracts, the water tank 52
is now rising and falling.

When the mold 12 comes above the water tank 52 due to the rotation of the rotary drive table 20, the cylinder 5
4 expands, the water tank 52 rises accordingly, and cold water is spouted from the shower nozzle 53 in the water tank 52 to the mold 12 attached to the top surface of the rotary drive table 20, so that the mold 12 is cooled. It's summery.

Next, the resin coating device provided in the first zone of the backing device for automobile mats will be explained.

As shown in FIG. 9, the resin coating device 70 applies a sol-like synthetic resin 71 to the rotary drive table 20.
This is a device that coats the inside of the mold 12 on the upper surface.

The resin coating device 70 includes an outer frame 72, an inner frame 73, and a resin tank 74. Above the rotary drive table 20 is a box-shaped inner frame 73.
is arranged so as to hang over the upper surface of the rotary drive table 20. Two left and right shafts 75 project from both upper ends of the inner frame 73, and running rollers 76 are rotatably attached to these shafts 75.
Further, this running roller 76 has an outer frame 7 consisting of a square upper frame 77 and a support 78 fixed to the outer edge of the rotary drive table 20 that supports the upper frame 77.
2, and is moved toward the center of the rotary drive table 20 on the upper frame 77 by a drive motor (not shown) fixed to the outer frame 72, and along with this, the inner frame 7
3 is designed to move horizontally.

A lifting cylinder 79 is fixed to the inner frame 73, and a plurality of resin coating nozzles 80 are attached to the tip of the shaft of this cylinder 79. A sol-like resin 71 is applied inside.

On the other hand, a resin tank 74 is arranged along the outer periphery of the rotary drive table 20 along with the outer frame 72 . In this resin tank 74, for example, 30~2-octylhexyl phthalate or n-octyl phthalate is added to vinyl chloride resin as a plasticizer.
Contains plastisol, which is made into a sol by mixing 35%. This resin 71 is the rotary drive table 20
The coating pump (which starts in conjunction with the resin coating cap opening/closing cylinder 82) passes through the coating cap 83, which is opened by the operation of the resin coating cap opening/closing cylinder 82 attached to the lower part of the tank 74 in accordance with the rotation of the tank 74. (not shown) to the coating pipe 84, and is applied by the above-mentioned method. Then, the resin 71 is applied from the resin application nozzle 80 onto the mold 12 on the upper surface of the rotary drive table 20.

The amount of resin 71 applied is adjusted by a coating plug 83 placed at the bottom of the resin tank 74. Furthermore, since the aforementioned heating device (not shown) is provided at the bottom of the rotary drive table 20 in this first zone, the resin 71 applied onto the mold 12 by the resin coating device 70 is heated by this. It is then heated and becomes semi-gelled, making it easy to weld to a fiber mat (not shown).

A deaerator 90 is provided adjacent to the resin coating device 70 and above the second zone.

As shown in FIG. 10, the degassing device 90 fills the mold 12 with the resin 71 coated on the mold 12 by the resin coating device (not shown). A large number of small tapered holes 10 are bored in the mold 12 to form anti-slip protrusions for an automobile mat, and it is necessary to fill these small holes 10 with resin 71.

The deaerator 90 is arranged such that a box-shaped frame 91 covers the upper surface of the mold 12, and an elevating cylinder 92 is attached to the upper part of the frame 91. This frame 91
An inner frame 93 is provided inside, and the shaft of the lifting cylinder 92 is attached to the upper part of the inner frame 93, so that the inner frame 93 moves up and down as the lifting cylinder 92 expands and contracts.
Also, rollers 94 are rotatably attached to the sides of the inner frame 93 and are in contact with the frame 91, so that as the inner frame 93 moves up and down, the rollers 94 rotate while in contact with the frame 91. There is. Therefore, when the inner frame 93 moves up and down, there is no wobbling, and the inner frame 93 can move up and down smoothly. The frame 91 also includes a square upper frame 95 and the table 2 that supports it.
It is supported by an outer frame 97 consisting of struts 96 fixed to the outer peripheral edge of the frame.

On the other hand, a vacuum pad 98 is attached to this inner frame 93.
is installed. The vacuum pad 98 has a rubber gasket 9 on the lower periphery that comes into contact with the edge of the mounting frame 26.
It has a trapezoidal shape with 9 pasted on it, and two air suction ports 100 are formed at the top.

One end of a hose 101 is attached to the air suction port 100 of this vacuum pad 98.
The other end is connected to a vacuum pump (not shown).

Then, when the mold 12 comes below the deaerator 90 due to the rotation of the rotary drive table 20, the lifting cylinder 92 of the frame 91 operates, and the vacuum pad 9
8 moves onto the resin 71 and comes into close contact with the edge of the mounting frame 26.

Furthermore, the air inside the vacuum pad 98 is removed by a vacuum pump (not shown), and the mold 12 and the resin 71 are removed.
Air bubbles existing between the two are removed, and the small tapered hole 10 provided in the mold 12 is also reliably filled with the resin 71. This makes it possible to reliably form small anti-slip protrusions on the back of the automobile mat, and also prevents cracks in the synthetic resin on the back of the fiber mat and separation of the fiber mat from the synthetic resin, which were caused by air bubbles. This will be prevented before it happens.

Note that a mold heating device is also provided below the rotary drive table in the second zone where the deaerator 90 is provided, and the resin in the mold is maintained in a semi-gelled state.

As shown in FIG. 1 and FIGS. 3 to 5, mold heating devices 30 are provided in zones 3 to 6 adjacent to this degassing device under the rotary drive table 20, respectively, and inside the mold 12. The resin 71 is kept in a semi-gelled state. In the case of the device provided in the sixth zone of this mold heating device 30, the rotary drive table 20
When the surface temperature of the resin 71 falls below 180°C based on a signal from a radiation temperature detector (not shown) that detects the surface temperature of the resin 71 in the mold 12 placed above, the resin is further heated. The temperature can be adjusted by lowering the temperature when it exceeds 180℃.

In the seventh zone, a fiber mat supply device 110 is provided on the outer peripheral edge of the rotary drive table, which moves in and out of the mold coated with resin and presses the fiber mat onto the resin under tension.

As shown in FIGS. 1 and 11, the fiber mat supply device 110 includes a conveyor device 111, a supply device 112, and a crimping device 113.

The conveyor device 111 is a conveyor 1 mounted rotatably in the direction of the rotary drive table 20 by a box-shaped pedestal 114 having a rectangular parallelepiped shape and a drive motor (not shown) installed inside the pedestal 114.
It consists of 15. Three fiber mats 14 are placed along the longitudinal direction on the upper surface of the conveyor 115 of this pedestal 114. This fiber mat 14 is made by driving a pile made of synthetic fiber into a base fabric 15.
The peripheral edge of the base fabric 15 is in a protruding state. The conveyor 115 is rotated by the drive of a drive motor (not shown), and the fiber mat 14 on the conveyor 115 is transferred in the direction of the rotary drive table 20. The fiber mat 14 transferred by the conveyor 115 is fed to the feeding device 11.
2 on the semi-gelled resin 71 on the upper surface of the rotary drive table 20.

The supply device 112 is arranged above the conveyor device 111, and similarly to the resin coating device described above,
A box-shaped frame 117 is arranged to cover the upper surface of the mold 12, and two shafts 1 on the left and right are attached to both ends of the upper part of the frame 117.
18 are provided in a protruding manner, and traveling rollers 119 are rotatably attached to these shafts 118. or,
This running roller 119 has an outer frame 122 consisting of a square upper frame 120 and a column 121 fixed to the outer edge of the table 20 that supports the upper frame 120.
The frame 117 is moved toward the center of the rotary drive table 20 on the outer frame 122 by a drive cylinder (not shown) fixed to the outer frame 122, and as a result, the frame 117 is horizontally moved. It's starting to move. A lifting cylinder 123 is attached to this frame 117. On the other hand, the shaft of this lifting cylinder 123 is attached to a box-shaped inner frame 124. A roller 125 is provided on each frame of the inner frame 124 in contact with the side edge of the frame 117, and when the inner frame 124 is raised or lowered, the roller 125
comes into contact with the side of the frame 117, so the inner frame 1
24 does not wobble. The lower four corners of the inner frame 124 are provided with claw-shaped 4
Two pins 126 are arranged facing outward. The shafts of cylinders 127 for rotating the pins are attached to the bases of these pins 126, and the cylinders 127
The pin 126 is provided so as to rotate outward as the pin 126 expands and contracts. These pins 126 are rotated and thrust into the four corners of the base fabric 15 protruding from the edge of the fiber mat 14 on the conveyor device 111. Also, the inner frame 12
Four bearings 128 are fixed to the lower part of the inner frame 124 along the longitudinal direction of the inner frame 124, and two threaded rods 129 threaded in opposite directions from the center to both ends are attached to the bearings 128. There is. Further, two drive motors 130 are fixed to the lower part of the inner frame 124, and the threaded rods 12
9 is adapted to be rotated by this drive motor 130. The bases of the pins 126 are screwed onto both ends of this one threaded rod 129, and as the threaded rod 129 rotates, the two pins 126 move horizontally toward and away from each other along the threaded rod 129. Each pin 126 can be positioned at the four corners of the fiber mat 14 according to the size of the mat 14. In this way, conveyor device 1
The fiber mat 14 on the fiber mat 11 is rotated so that the pins 126 aligned with the four corners of the base fabric 15 protruding from its edge are pushed through, and in this state, the inner frame 12 is inserted.
4 lifting cylinder 123 and outer frame 122
is lifted by a cylinder (not shown),
The fiber mat 14 is moved and placed on the resin 71 on the mold 12.

Further, the inner frame 124 is further provided with a crimping device 113 in the center thereof. The crimping device 113 is attached to a head 131 having a flat shape that presses the upper surface of the fiber mat 14 placed on the resin 71 on the mold 12 described above, and is attached vertically to the top of this head 131. and a pressure cylinder 132 for pressurizing the fiber mat 14. And the crimping device 113 and the pin 1
26, the fiber mat 1 is pulled with the four corners of the base fabric 15 protruding from the edge of the fiber mat 14 being stretched.
4 and the semi-gelled resin 71 are pressurized and are completely welded and integrated without any gaps between them.

As shown in FIGS. 1, 2, and 5, following this welding device, five mold heating devices are provided below the rotary drive table in zones 8 to 12. In addition, the above-mentioned cooling device is installed at the bottom of the rotary drive table in the 13th zone and the 14th zone.
By cooling the semi-gelled resin, it changes to a rubber-like gelled state.

In addition, the 14th zone is equipped with a mold changing device as well as a cooling device.

As shown in FIGS. 1 and 12, the mold changing device 140 is a device that replaces the mold 12 on the rotary drive table 20 depending on the type of automobile mat to be manufactured. This mold changing device 140
A box-shaped frame 141 is arranged to cover the top surface of the table 20, and a lifting cylinder 142 is attached to the top of this frame 141. An inner frame 143 is installed inside this frame 141, and the shaft of the lifting cylinder 142 is attached to the upper part of this inner frame 143, so that the inner frame 143 moves up and down as the cylinder 142 expands and contracts. . Further, a roller 144 is rotatably attached to the side of the inner frame 143, and a roller 144 is rotatably attached to the side of the inner frame 143.
41 and as the inner frame 143 moves up and down, the roller 144 rotates while in contact with the frame 141. Therefore, the inner frame 143
There is no rattling when going up and down, and it is possible to go up and down smoothly. In addition, there are two shafts 1 on the left and right at both ends of the upper part of the frame 141.
52 are provided in a protruding manner, and traveling rollers 153 are rotatably attached to these shafts 152. or,
This running roller 153 is an outer frame 14 made up of a square upper frame 145 and a column 146 fixed to the outer edge of the table 20 that supports the upper frame 145.
7 and is moved toward the center of the rotary drive table 20 on the upper frame 145 by a drive cylinder (not shown) fixed to the outer frame 147, and along with this, the inner frame 143 is moving horizontally.

This inner frame 143 has a lifting cylinder 14
2 is attached, and a vacuum suction pad 148 is attached to the tip of the shaft of this lifting cylinder 142.

The vacuum suction pad 148 is bowl-shaped with a rubber gasket 149 attached to the lower periphery that contacts the mold 12, and has an air suction port 150 formed in the upper part. One end of a hose 151 is attached to the air suction port 150 of the vacuum suction pad 148, and the other end of the hose 151 is connected to a vacuum pump (not shown).

When replacing the mold 12, the lifting cylinder 142 of the inner frame 143 and the drive motor (not shown) of the outer frame 147 are operated according to the rotation of the rotary drive table 20, and the vacuum suction pad 148 is activated. It is moved onto the mold 12 and brought into close contact with the mold 12.

Then, a vacuum pump (not shown) is operated to suction and remove the mold 12, and a different type of mold 12 is attached to the vacuum suction pad 148 and again attached to the mounting frame 26 of the rotary drive table 20.

As shown in Figure 13, the 15th zone has resin 7.
A removing device 160 for peeling off the fiber mat 14 buckled by the mold 12 from the mold 12 is provided at the outer peripheral edge of the rotary drive table 20.

The removal device 160 includes a clamp device 161, an inner frame 163, and an outer frame 164. Above the table 20 is a box-shaped frame 162.
is arranged so as to cover the upper surface of the mold 12, and this frame 16
A lifting cylinder 170 is attached to the upper part of 2. An inner frame 163 is installed inside this frame 162, and the shaft of the lifting cylinder 170 is attached to the upper part of this inner frame 163, and as the lifting cylinder 170 expands and contracts, the inner frame 16
3 is designed to go up and down. Further, a roller 171 is rotatably attached to the side of the inner frame 163 and comes into contact with the frame 162, so that the roller 171 moves up and down the frame 16 as the inner frame 163 moves up and down.
It rotates while in contact with 2.
Therefore, when the inner frame 163 moves up and down, there is no rattling, and the inner frame 163 can move up and down smoothly. Further, two left and right shafts 174 are protruded from both ends of the upper part of the frame 162, and these shafts 1
A running roller 175 is rotatably attached to 74. Further, this running roller 175 is supported by an outer frame 164 consisting of a square upper frame 172 and a column 173 fixed to the outer edge of the table 20 that supports the upper frame 172, and is fixed to this outer frame 164. The upper frame 172 is rotated by a drive cylinder (not shown) and moved toward the center of the table 20, and the inner frame 163 is moved horizontally accordingly.

This inner frame 163 has a lifting cylinder 17
0 is fixed, and a clamp device 161 is fixed to the tip of the shaft of this cylinder 170.

The clamping device 161 includes a clamping claw 1 disposed on the rotary drive table 20 side at the bottom of the inner frame 163.
65, and a support rod 16 that supports the end of the fiber mat 14 while sandwiching it when the claw 165 rotates.
6, an air nozzle 167 provided further outside of the clamp claw 165, that is, on the table 20 side, and a cylinder with the tip of a shaft 168 attached to the base of the clamp claw 165 arranged on the opposite side of the lower part of the inner frame 163. 169.

And, regarding this removal device 160,
According to the rotation of the rotary drive table 20, the inner frame 163 moves horizontally and vertically onto the fiber mat 14 of the rotary drive table 20, and then air is ejected from the air nozzle 167 of the clamping device 161 at the bottom of the inner frame 163. 14 fiber mats
One end of the base fabric 15 with protruding teeth is turned up, the clamp claw 165 is rotated in the direction of the arrow in the figure by the cylinder 169, and the fiber mat 14 is turned up.
With one end held between the claw 165 and the support rod 166, the inner frame 163 moves horizontally and vertically again and is placed on the table lifter 176 whose top surface is always kept at a constant height by a sensor. The fiber mat 14 is adapted to be moved.

The bucking device 11 for automobile mats of the present invention is not limited to the one described above, but the molds attached to the upper surface of the rotary drive table are arranged in pairs in the width direction of the rotary drive table, and the molds are attached to the periphery of the table. Two of each device provided in the table may be provided on the inside and outside of the table. In this case, the efficiency of backing can be further improved.

(Effects of the Invention) As detailed above, the present invention includes a rotary drive table on which a plurality of molds are replaceably assembled, a resin coating device that applies resin onto the molds,
a deaeration device that fills the applied resin into the mold;
A mold heating device installed at the bottom of the rotary drive table, a fiber mat supply device that moves in and out of the mold coated with resin and presses the fiber mat onto the resin under tension, and a fiber mat supply device installed at the bottom of the rotary drive table. This is a backing device for automobile mats, characterized in that it is equipped with a mold cooling device and a removal device for peeling off the resin-backed fiber mat from the mold.

Therefore, in the case of the automobile mat bucking device of the present invention, the feeding of fiber mats, the removal of manufactured automobile mats from the mold, the application of synthetic resin, the heating and cooling of the mold, etc. are all covered. Since the process is carried out continuously by rotating the device and by mechanical operation, it is possible to always produce uniform products.

In addition, in the case of the automobile mat backing device of the present invention, supply of fiber mats, removal of manufactured automobile mats from molds, coating with synthetic resin, heating and cooling of the molds, etc. are all carried out by the device. Since the process is performed by mechanical operation, the amount of work required by the operator can be significantly reduced.

Furthermore, since a large number of molds can be assembled on the rotary drive table, many types of automobile mats can be manufactured at the same time.

[Brief explanation of the drawing]

FIG. 1 is a plan view showing the entire backing device for an automobile mat of the present invention, FIG. 2 is a side view showing the drive device and rotary drive table of the bucking device for an automobile mat of the invention, and FIG. FIG. 4 is a front view of the mold heating device, FIG. 5 is a side view, and FIG. 6 is a plan view of the mold heating device of the automobile mat bucking device of the present invention. A perspective view of a mold cooling device of a bucking device, FIGS. 7 and 8 are side views showing the mold cooling device, and FIG. 9 is a perspective view of a resin coating device of a bucking device for an automobile mat according to the present invention. , FIG. 10 is a perspective view showing a degassing device of the automobile mat bucking device of the present invention, FIG. 11 is a perspective view showing a fiber mat supply device of the automobile mat bucking device of the present invention, and FIG. FIG. 13 is a perspective view showing a mold changing device of an automobile mat bucking device of the present invention, FIG. 13 is a perspective view showing a fiber mat removal device of the automobile mat bucking device of the present invention, and FIG. 14 is a conventional Plan view showing a backing device for automobile mats, 1st
FIG. 5 is a side view as well. Explanation of symbols, 11... Automobile mat bucking device, 20... Rotary drive table, 30...
Mold heating device, 50... Mold cooling device, 70...
Resin coating device, 90... Deaeration device, 110... Fiber mat supply device, 140... Mold replacement device, 1
60...Removal device.

Claims (1)

[Claims] 1. A rotary drive table with a plurality of molds attached to its upper surface so that they can be exchanged, a resin coating device that applies resin onto the molds, a deaerator that fills the molds with the applied resin, and a rotary drive table. A mold heating device installed at the bottom of the table, a fiber mat supply device that moves in and out of the mold coated with resin and presses the fiber mat onto the resin under tension, and a fiber mat supply device installed at the bottom of the rotary drive table. A backing device for automobile mats, comprising a mold cooling device and a removal device for peeling fiber mats backed by resin from the mold.