JPH0549024B2 - - 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) As a conventional bucking device of this type, one shown in Japanese Patent Publication No. 56-37047 has been proposed, and this bucking device 1 is shown in FIGS. 17 and 1.
As shown in Fig. 8, 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, and these carts 5 move on the track 4 intermittently. In addition to being movable, a plastisol supply device 6, a pressurizing device 7, and a cooling device 8 are provided at predetermined locations along the track 4, respectively. This bucking device 1 heats plastisol supplied into a mold 2 by a plastisol supply device 6 with a heating device 3 provided at the bottom of a trolley 5 to semi-gel, and then a fiber mat 9 is placed on the upper surface of the plastisol to form a fiber. The fiber mat 9 is cooled by cooling the mat 9 with the cooling device 8.
Plastisol in the mold 2 is turned into a sol without being exposed to heat.

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

In addition, with this 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. If the time 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, resulting in adverse effects such as defective products. It was hot.

Furthermore, in the case of conventional bucking equipment, a ring-shaped track is installed in the factory, and the cart moves on this track to back the fiber mats, which only increases the size of the machine. However, a large space was required to install such equipment.

This invention was made in view of these problems, and it eliminates the work of removing the fiber mat, makes it possible to always produce uniform products, and also makes the device more compact so that it can be installed even in a small space. An object of the present invention is to provide a backing device for automobile mats that can be installed.

(Means for Solving the Problems) That is, the present invention provides a mold heating device for heating a mold, a mold cooling device adjacent to the mold heating device, and a mold heating device and a mold. A movable table that moves horizontally on the top surface of the cooling device and has a plurality of molds attached thereto in a replaceable manner; a resin coating device that is disposed on the side of the mold cooling device and applies resin onto the molds; The deaerator moves up and down on the mold cooling device to fill the mold with the applied resin, and the deaerator moves in and out of the mold heating device, with the resin being applied to the top of the mold heating device. A fiber mat supply device that compresses the fiber mat under tension onto the resin on the moving table, and a fiber mat supply device that moves in and out of the mold cooling device, and the fiber mat backed by the resin is placed on the moving table. This is a backing device for automobile mats, characterized in that it is equipped with a removal device for peeling fiber mats from a mold.

(Function) Therefore, in the automobile mat bucking device of the present invention, the feeding and removal of fiber mats, the supply of synthetic resin, the heating and cooling of the mold, and the movement of the mold are all performed by the machine of the device. Since the process is now carried out manually, it is no longer necessary for the operator to perform complicated operations, and at the same time, it has become possible to always produce uniform products.

In addition, in the automobile mat bucking device of the present invention, the fiber mat supply, removal,
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.

Furthermore, in the automobile mat bucking device of the present invention, a moving table, a resin coating device, a fiber mat supply device, a degassing device, and a removal device are provided on the mold heating device and the mold cooling device, so that the bucking device can be easily removed. The device can be made compact and can be installed even in a small space.

(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, FIG. 2 is a front view showing the entire bucking device for an automobile mat according to the invention, and FIG. FIG. 1 is a side view showing the entire backing device for an automobile mat.

As shown in FIGS. 1 to 3, bucking device 11
Each device is provided above or to the side of a mold heating device 20 and a mold cooling device 40 provided adjacent to this mold heating device 20.

This bucking device 11 has a box shape and can be divided into four parts from the viewpoint of function. That is,
If the position of the mold heating device 20 is the A zone, and the position of the mold cooling device 40 provided adjacent to this mold heating device 20 is the B zone, then the mold heating device and the mold are located in the A zone and the B zone. A moving table 60 is provided to horizontally reciprocate above the mold cooling device. Further, a resin coating device 80 is provided on the side of the mold cooling device 40 in the B zone, and a degassing device 100 is provided above the mold cooling device 40 in the B zone so as to be movable up and down. . Furthermore, a removal device 150 that enters and exits onto the mold cooling device 40 in the B zone and removes the butted fiber mat 13 is adjacent to the D zone.

On the other hand, a fiber mat supply device 120 that enters and exits onto the mold heating device 20 in the A zone and supplies the fiber mat 13 onto the resin 12 is provided in the C zone adjacent to the mold heating device 20.

As shown in FIGS. 1 to 4, the mold heating device 20 in the A zone is composed of a frame 21 fixed on a concrete base and a gas burner 22 provided on the frame 21. In this embodiment, the mold heating device 20 is set so that the temperature of the mold 14 assembled on the moving table 60 is approximately 180°C. Also, gas burner 22
A gas pipe burner type is used. A duct (not shown) in which a firing blower and an exhaust fan are respectively attached is arranged outside the mold heating device 20. Then, the mold 14 is assembled by the movement of the movable table 60, and when the movable table 60 with the resin 12 coated on the mold 14 comes onto the mold heating device 20, the mold on the upper surface of the movable table 60 14 is heated directly from below the table 60. In this way, the sol-like resin 12 in the mold 14 is semi-gelled. Furthermore, a radiation temperature detector 24 is provided above the mold heating device 20 to detect the surface temperature of the resin 12 within the mold 14. Based on the signal from the radiation temperature sensor 24, the temperature can be adjusted by further heating the resin 12 when the surface temperature of the resin 12 is below 180°C, or by cooling it when the surface temperature is above 180°C. It's becoming like that.

The set temperature of the radiation temperature detector 24 is 180℃.
However, it is determined by taking into account the type of resin, the material of the fiber mat, etc.

As shown in Figs. 1 to 4, this mold heating device 2
A mold cooling device 40 is provided in the B zone adjacent to the mold cooling device 40. The mold cooling device 40 includes a water tank 41 fixed on a concrete foundation and a shower nozzle 42 projecting into the water layer 41. The water tank 41 is formed into a box shape. When the fiber mat 13 backed by the resin 12 comes onto the mold cooling device 40 by the movement of the moving table 60, it is directly applied to the bottom surface of the mold 14 assembled on the top surface of the moving table 60 in the water tank 41. Cold water is spouted from the shower nozzle 42 to cool the mold 14.

As shown in FIG. 1 and FIGS. 3 to 5, a moving table 60 is provided to horizontally reciprocate above the mold heating device 20 and mold cooling device 40 in the A zone and B zone. ing. This moving table 60 includes an upper moving table 61 and a lower moving table 71.

The upper moving table 61 is provided so as to straddle the mold heating device 20 and the mold cooling device 40 described above. An elevating body 62 having an elevating motor (not shown) installed therein is attached to the four corners of the upper moving table 61. The elevating body 62 is screwed onto threaded rods 64 which are provided at the four corners of the table 61 and extend vertically in parallel. As the elevating motor (not shown) rotates, the elevating body 62 moves up and down along the threaded rod 64, and the upper moving table 61 moves up and down.

Racks 65 are attached to the upper surface of both ends of the upper moving table 61. Further, a drive motor 68 with pinions 66 attached on both sides is mounted on the support frame 16 erected on the side wall 15 on both sides of the mold heating device 20 and mold cooling device 40 in the A zone and B zone. A rotating shaft 67 is installed horizontally. And the upper moving table 61
is raised in the X direction in FIG. 5, so that the rack 65 is screwed into pinions 66 at both ends of the rotating shaft 67. As a result, the mold heating device 2
Power from a drive motor 68 disposed on the outside of the lower part of the 0 is transmitted to the rotating shaft 67 via a chain 69, causing the pinion 66 to rotate. A moving table 61 is adapted to move in the horizontal direction. Two assembly frames 17 for assembling the molds 14 are formed on the upper surface of the upper moving table 61. A hole 10 slightly smaller than the mold 14 is formed in the assembly frame 17. The mold 14, which is replaceably assembled on the upper surface of the upper movable table 61, is an externally formed plate measuring 120 mm x 80 mm x 10 mm, and is formed to match the size of an automobile mat. There are various molds 14 depending on the size of the automobile mat.
It is replaceably assembled into the assembly frame 17 as required. Therefore, in this embodiment, four molds 14 can be assembled into the apparatus, including the lower moving table to be described later.
Up to four types of automotive mats can be manufactured. A mold fixture 18 is provided on the upper surface of the upper movable table at each peripheral portion of this assembly frame 17,
When the mold 14 is assembled to the assembly frame 17, it is fixed.

The lower moving table 71 is the upper moving table 61
It is formed slightly smaller than the upper moving table 61, is provided below the upper moving table 61, and can be moved independently of the upper moving table 61. There are two cars 72 at each end of the lower moving table 71.
is rotatably protruded. This wheel 72 is placed on the upper surface of the both side walls 15, and is adapted to move horizontally on this upper surface.

On the other hand, racks 73 are attached to the lower surface of both ends of the lower moving table 71. This rack 73
are adapted to be screwed into pinions 75 at both ends of a rotating shaft 74 installed horizontally on both side walls 15. Power from a drive motor (not shown) is transmitted to the rotating shaft 74 via a chain (not shown) to rotate the pinion 75, and the lower movable table has racks 73 on both sides of the lower surface that are screwed into the pinion 75. 71 is adapted to move horizontally.

Next, the resin coating device disposed on the side of the mold cooling device of the automobile mat bucking device of the present invention will be explained.

As shown in FIGS. 1 to 3 and 6, the resin coating device 80 includes a movable table 6 on which a mold 14 is assembled.
0 is moved onto the mold cooling device 40 in the B zone, this device moves in and out on this moving table 60 toward the A zone and coats the resin 12 onto the mold 14.

The resin coating device 80 includes an inner frame 81 and a resin tank 91. A plurality of resin application nozzles 82 are attached to the inner frame 81. From these resin application nozzles 82 to the moving table 6
A sol-like resin 12 is applied onto a mold 14 in a compressed state. A rotating shaft 86 with pinions 87 attached on both sides is horizontally installed at both lower ends of the inner frame 81. Said both side walls 15
A rack 85 into which the pinion 87 is screwed is mounted on the top. The power of a drive motor 88 attached to the inner frame 81 is transmitted to the rotating shaft 86 via a chain 89, and the pinion 87
rotates, and the inner frame 81 moves horizontally accordingly. By horizontally moving the inner frame 81 in the direction of the A zone, the plurality of resin coating nozzles 82 of the inner frame 81 move in and out on the moving table 60, and the mold 1
4, a resin 12 is applied thereto.

On the other hand, the resin tank 93 includes a cylinder 92 for opening and closing the resin coating plug and a coating plug 93. Inside the resin tank 91, plastisol, which is made by mixing 30 to 35% of 2-octylhexyl phthalate or n-octyl phthalate as a plasticizer with vinyl chloride resin, is stored. As the movable table 60 moves, the resin 12 passes through the coating plug 93 opened by the operation of the resin coating cap opening/closing cylinder 92 attached to the lower part of the tank 91, and enters the resin coating cap opening/closing cylinder 92. The resin is transferred to a coating pipe 94 by a coating pump (not shown) which is started in conjunction with the resin, and is coated onto the mold 14 by a resin coating cylinder 82. Note that the amount of resin 12 applied is based on the resin tank 9.
It is adapted to be adjusted by an applicator plug 93 arranged at the bottom of 1.

A deaerator is provided above the mold cooling device together with the resin coating device.

The degassing device fills the mold with the resin coated on the mold by the resin coating device. The mold has a large number of tapered small holes 190 for forming anti-slip protrusions of an automobile mat, and it is necessary to fill these small holes 190 with resin.

As shown in FIG. 7, the degassing device 100 is configured such that two box-shaped vacuum pads 101 are lined up in a mold 1.
4. Arranged to cover the top surface. Elevating cylinders 102 are attached to the upper portions of the vacuum pads 101, respectively. These lifting cylinders 10
2 is attached to a rectangular upper plate 103 supported by support frames 16 on both side walls 15. Also, each vacuum pad 1 is placed on this upper plate 103.
Two drip prevention covers 104 are rotatably attached to cover 01 from below.

The vacuum pad 101 is a trapezoidal type that comes into contact with the assembly frame 17 of the two molds 14 of the moving table 60, and a rubber gasket 106 is attached to the lower periphery. Two air suction ports 107 are formed in the upper part of this vacuum pad 101. One end of a hose 108 is attached to the air suction port 107 of this vacuum pad 101, and the other end of this hose 108 is connected to a vacuum pump (not shown).

After the resin 12 is applied onto the mold 14 by the resin coating device, the vacuum pad 101 of the deaerator 100 is lowered by the operation of the lifting cylinder 102 and comes into contact with the assembly frame 17 of the mold 14. They are starting to come into close contact.

Furthermore, the air inside the vacuum pad 101 is removed by a vacuum pump (not shown), and the mold 14 and the resin 1 are removed.
The air bubbles existing between the mold 14 and the mold 14 are removed.
The resin 1 is reliably inserted into the tapered small hole 190 provided in the
2 is now filled. 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.

The C zone is provided with a fiber mat supply device that goes in and out of the mold heating device in the A zone and presses the fiber mat onto the upper surface of the resin in the mold under tension.

As shown in FIGS. 1 to 3 and 8 to 11, this fiber mat supply device 120 applies the resin 12 into the mold 14 by the resin coating device 80 in the B zone, and then applies the resin 12 in the B zone. After the resin 12 is filled into the mold 14 by the deaerator 100, the movable table 60 is moved onto the mold heating device 20 in the A zone, and the mold heating device 20 is heated at a predetermined temperature for a predetermined period of time. A fiber mat 13 is pressed onto the upper surface of the resin 12 in the mold 14, which has been heated and turned into a semi-gel.

This fiber mat supplying device 120 is equipped with four support frames 121 vertically arranged in parallel at the four corners of the C zone, and an inner frame 122 provided within the support frames 121.

The inner frame 122 is formed into a plate shape. The lower frame 122 has hooks 135 at the four corners that can be hooked onto the fiber mat 13.
A lifting cylinder 127 for lifting and lowering the fiber mat 13 and a pressure cylinder 142 for lifting and lowering the head 143 for pressurizing the fiber mat 13 are attached.

A drive motor 131 is mounted on the upper surface of the inner frame 122.
is installed. A rotating shaft 129 is fixed to both ends of the upper surface of the same inner frame 122, and a chain 132 is hooked to both ends. A pinion 130 is attached to both ends of the rotating shaft 129, and power from the drive motor 131 is transmitted to the rotating shaft 129 via a chain 132, causing the pinion 130 to rotate.

A rack 128 installed horizontally on the support frames 16 and 121 is screwed into this pinion 130 so as to span the A zone and C zone, and as the pinion rotates, an inner frame 122 with racks 128 attached to both ends of the upper part is screwed into the pinion 130. It is designed to move horizontally within the A zone and C zone. Further, two shafts 138 are provided protruding from both sides of the upper surface of the inner frame 122, and running rollers 139 are attached to these shafts 138. This running roller 139 runs parallel to the rack 128 on a rail 133 attached to the support frames 16, 121.

Lower frame 12 below this inner frame 122
Toothbrush-like claws 135 with a plurality of needles 134 arranged side by side are attached to the four corners of 6. these nails 1
A shaft 137 of a rotation cylinder 136 for rotating the claw 135 is attached to the base of the rotation cylinder 135, and the claw 135 is provided to rotate outward as the rotation cylinder 136 expands and contracts. Then, a nail 1 is attached to the base cloth 19 which is protruding from the edge of the fiber mat 13 on the workbench 140 placed below.
35 rotates and pierces.

In this way, the nails 135 pierce the base fabric 15 of the fiber mat 13 on the workbench 140, and the fiber mat 1
3 is lifted up by the lifting cylinder 127 while being pulled in the horizontal direction. Then, by the horizontal movement of the inner frame 122, it is moved onto the resin 12 of the mold 14, and the lifting cylinder 127 is moved again.
The fiber mat 13 is placed thereon.

A pressure cylinder 142 attached to the inner frame 122 is attached with a flat head 143 that presses the upper surface of the fiber mat 13.

Then, by the head 143 and the claws 135, the fiber mat 13 is pulled horizontally and pressed against the semi-gelled resin 12, and the two are completely welded without any gaps.

After the semi-gelled resin and the fiber mat are welded by the fiber mat supply device in this manner, the resin is further heated by the mold heating device in order to completely weld the resin. After the mold is sufficiently heated, the moving table is moved onto the mold cooling device in the B zone, and the mold is cooled.
When the resin is in a semi-gelled state, it changes to a rubber-like gelled state by cooling.

The D zone is provided with a removal device for peeling off the resin-backed fiber mat from the mold.

As shown in FIGS. 1 to 3 and 12 to 15, the removal device 150 consists of four support frames 151 vertically arranged in parallel at the four corners of the D zone.
An inner frame 152 and a clamp device 153 are provided within the support frame 151.

The inner frame 152 is formed into a plate shape.

A drive motor 161 is mounted on the upper surface of the inner frame 152.
is installed. Similarly, a rotating shaft 159 is fixed to both ends of the upper surface of the inner frame 152, and a chain 162 is hooked to both ends. Rotating shaft 15
A pinion 160 is attached to both ends of the drive motor 161, and the power of the drive motor 161 is transmitted to the rotating shaft 159 through a chain 162, causing the pinion 160 to rotate.

A rack 158 horizontally installed on the support frames 16, 151 is screwed into this pinion 160 so as to span the B zone and the D zone.
As the inner frame 152 rotates, the inner frame 152 with racks 158 attached to both ends of the upper part moves horizontally within the B zone and the D zone. Further, two shafts 156 are bored on both sides of the upper surface of the inner frame 152, and running rollers 157 are attached to these shafts 156. This running roller 157 runs parallel to the rack 158, supporting frame 16,
It is designed to run on rails 163 attached to 151.

A clamp device 1 is attached to the tip of the shaft of the lifting cylinder 164 fixed to the inner frame 152.
53 is fixed.

The clamp device 153 includes a plurality of clamp claws 165 disposed on the movable table 60 side at the bottom of the inner frame 152, and a plurality of supports that support the end of the fiber mat 13 while sandwiching it when the clamp claws 165 rotate. A plate 166, an air nozzle 167,
It consists of a cylinder 169 in which the tip of a shaft 168 is attached to the base of the clamp claw 165.

And, regarding this removal device 150,
Fiber mat 13 backed with resin
is moved onto the mold cooling device 40 in the B zone by the moving table 60, and cooled by the mold cooling device 40 to change the resin 12 of the fiber mat 13 from a semi-gelled state to a gelled state. After that, the drive motor 161 of the inner frame 152 is driven to horizontally move the inner frame 152 onto the fiber mat 14 on the moving table 60.

Then, the lifting cylinder 155 is extended, the clamp device 153 at the lower part of the inner frame 152 is lowered, air is ejected from the air nozzle 167, and one end of the base fabric 19 of the fiber mat 13 is turned up. At this time, the clamp claw 16
5 is rotated in the direction of the arrow in the figure by a cylinder 169, and one end of the turned-up fiber mat 13 is held by the claw 1.
65 and the support plate 166.
The clamping device 153 that has clamped the fiber mat 13 in this manner rises, and the inner frame 152 moves horizontally again to move the fiber mat 13 onto a table lifter (not shown).

A sensor (not shown) is provided between the plurality of support plates 166 of the clamping device 153, so that when the clamping device 153 does not completely clamp the fiber mat 13, the fiber mat 13 is removed again. It's getting old.

As shown in FIG. 16, a mold changing device 180 is provided outside the A zone to replace and replace the mold 14 on the movable table 60 depending on the type of automobile mat to be manufactured. It is being

In addition, in the case of the automobile mat bucking station 11 of the present invention, each of the above-mentioned devices can be operated separately. For example, in zone B, a resin supply device and a deaerator are used to apply resin onto the mold on the upper movable table and to fill the mold with resin, and at the same time, in zone A, a mold heating device is used to apply resin to the mold on the upper movable table. The resin on the mold of the movable table is semi-gelled, a fiber mat is supplied onto this resin by a fiber mat supply device, and the resin is further heated for a predetermined period of time by a mold heating device. Then, the upper moving table is moved to the A zone, and the lower moving table is moved to the B zone. In the A zone, the resin is heated and the fiber mat is supplied as described above. In zone B, a mold cooling device and a removal device cool the resin and remove the fiber mat. If each device is programmed in this manner and operated under computer control, the efficiency of bucking work can be further improved. Furthermore, when the number of fiber mat backing operations is small, the apparatus may be operated in sequence for each process.

In addition, in the case of the backing device of the automobile mat of the present invention, the device for horizontal movement or vertical movement is not limited to the above-mentioned device, and any device may be used.

(Effects of the Invention) As detailed above, the present invention provides a mold heating device for heating a mold, a mold cooling device adjacent to the mold heating device, and a mold heating device and a mold cooling device. A movable table that moves horizontally on the top surface of the device and has a plurality of molds attached thereto in a replaceable manner; a resin coating device disposed on the side of the mold cooling device that applies resin onto the molds; and a mold. The deaerator moves up and down on the cooling device to fill the mold with the applied resin, and the deaerator moves in and out of the mold heating device, with the resin coated on the top of the mold heating device. A fiber mat supply device that compresses the fiber mat under tension onto the resin on the moving table, and a fiber mat supply device that moves in and out of the mold cooling device, and the fiber mat backed by the resin is placed on the moving table. This is a backing device for automobile mats, characterized in that it is equipped with a removal device for peeling fiber mats from a mold.

Therefore, in the automobile mat bucking device of the present invention, feeding and removal of fiber mats, feeding of synthetic resin, heating and cooling of the mold, movement of the mold, etc. are all performed by the mechanical operation of the device. Because of this, uniform products can always be manufactured.

In addition, in the automobile mat bucking device of the present invention, the fiber mat supply, removal,
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.

Furthermore, in the bucking device for automobile mats of the present invention, each device is provided on the mold heating device and the mold cooling device, so that the bucking device can be made compact, and the device can be installed even in a small space. can be installed.

[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 front view, FIG. 3 is a side view, and FIG. 4 is a bucking device for an automobile mat of the present invention. 5 is a side view showing a moving table of the backing device for an automobile mat of the present invention, and FIG. 6 is a cross-sectional view showing a mold heating device and a mold cooling device of the invention. FIG. 7 is a perspective view showing a resin coating device of a bucking device; FIG. 7 is a perspective view showing a deaeration device of a bucking device for an automobile mat of the present invention;
FIG. 8 is a front view showing the fiber mat supply device of the automobile mat bucking device of the present invention; FIG.
The figure is also a plan view of the fiber mat supply device, No. 10.
The figure is also a side view of the fiber mat supply device, No. 11.
The same figure is an enlarged side view of the main part of the fiber mat supply device, FIG.
14 and 15 are enlarged side views of main parts showing the process of removing the fiber mat with the removal device, FIG. 16 is a perspective view showing the mold supply device, and FIG. 17 is a front view showing the removal device. The figure is a plan view showing a conventional car mat bucking device.
FIG. 18 is also a partial sectional view of the bucking device. 11... Bucking device, 20... Mold heating device, 40... Mold cooling device, 60... Moving table, 80... Resin coating device, 100... Deaerator, 120... Fiber mat supply device, 150...
Removal device.

Claims (1)

[Claims] 1. A mold heating device that heats the mold, a mold cooling device adjacent to the mold heating device, and a mold heating device and a mold cooling device that horizontally move the upper surfaces of the mold heating device and the mold cooling device.
a movable table on which a plurality of molds are replaceably assembled on the upper surface, and a movable table disposed on the side of the mold cooling device,
There is a resin coating device that applies resin onto the mold, a deaerator that moves up and down above the mold cooling device and fills the applied resin into the mold, and a degassing device that moves in and out of the mold heating device to remove the resin. A fiber mat supply device that presses the fiber mat under tension onto the resin of a moving table that is moved with resin applied to the upper surface of the mold heating device, and a fiber mat supply device that presses the fiber mat in a tensile state onto the resin that is moved with the resin applied to the upper surface of the mold heating device. 1. A backing device for automobile mats, comprising a removal device for peeling off a fiber mat on a movable table with the mat placed thereon from a mold.