Abstract
A device for turning over molds is provided that can reduce the wear of turning over wheels and supporting rollers even when the speed for transporting a flask or the speed for turning it over increases. A pair of turning over wheels (5) are attached to respective sides of a turning over roller conveyor (4), on which a metal flask (3) is mounted. The outer surfaces of the wheels are supported by respective pairs of supporting rollers (6). A driving roller (9) is provided on one or both of the wheels. The supporting rollers are flangeless. Two pairs of side rollers (10) abut the side surfaces of the wheels so as to prevent them from moving in the direction in which the flask is transported. The side rollers are preferably configured so that their surfaces that contact the wheels are formed as arcs.
Claims
1. A device for turning over molds, wherein a pair of turning over wheels are attached to respective sides of a turning over roller conveyor, on which a metal flask is mounted, wherein outer surfaces of the pair of turning over wheels are supported by means of respective pairs of supporting rollers, and wherein a driving roller is provided on one or both of the turning over wheels, the device being characterized in that the supporting rollers are configured with no flange, and two pairs of side rollers abut side surfaces of the turning over wheels so as to prevent the turning over wheels from moving in a direction in which the metal flask is transported.
2. The device for turning over molds of claim 1, wherein scrapers for cleaning tread surfaces are provided at respective positions to contact the tread surfaces of the turning over wheels, wherein a scraper, which is propelled by a spring, is housed in a bracket of each of the scrapers for cleaning tread surfaces.
3. The device for turning over molds of claim 1, wherein the side rollers are configured so that their surfaces that contact side surfaces of the turning over wheels are formed as arcs.
4. The device for turning over molds of claim 3, wherein scrapers for cleaning tread surfaces are provided at respective positions to contact the tread surfaces of the turning over wheels, wherein a scraper, which is propelled by a spring, is housed in a bracket of each of the scrapers for cleaning tread surfaces.
Description
BRIEF DESCRIPTION OF DRAWINGS
(1) FIG. 1 is a partially-sectional front view of an embodiment of the present invention.
(2) FIG. 2 is a side view of the embodiment of the present invention.
(3) FIG. 3 is an enlarged side view of the side roller.
(4) FIG. 4 is a side view of another embodiment of the present invention.
(5) FIG. 5 is a chart of the system of the pneumatic piping for an air cushion.
(6) FIG. 6 is a partially-sectional front view of another embodiment of the present invention.
(7) FIG. 7 is an enlarged sectional view of a part for attaching a liner of the turning over wheels.
(8) FIG. 8 is a front view of a conventional device for turning over the molds.
(9) FIG. 9 is a side view of the conventional device for turning over the molds.
DESCRIPTION OF EMBODIMENTS
(10) Below, the embodiments of the present invention are discussed. In FIG. 1 the reference number 1 denotes a device for turning over the molds of the present invention. The device is used in the line for tight flask molding so as to turn over a mold that has been molded within a metal flask and has been transported to the device. The device repeats normal and reverse rotations at 180 to turn over the molds. The reference number 2 denotes a conveyor with stationary rollers that transports a metal flask 3. The reference number 4 denotes a turning over roller conveyor that is located in the middle of the conveyor 2 with stationary rollers. The arrow Y1 denotes the direction in which the metal flask 3 is transported.
(11) The turning over roller conveyor 4 causes one metal flask 3 to be mounted on it to turn over the metal flask 3. At both the front and the end of it ring-shaped turning over wheels 5 are provided. The turning over roller conveyor 4 is fixed to the turning over wheels 5 so as to be turned over together with the turning over wheels 5. The metal flask 3 is transported from the conveyor 2 with the stationary rollers through the center hole of one of the turning over wheels 5 to the turning over roller conveyor 4. The metal flask 3 is transported between a pair of rollers with flanges 4a that are located at the upper and lower parts of the turning over roller conveyor 4.
(12) As in FIG. 2, each of the turning over wheels 5 is supported by respective pairs of the supporting rollers 6. These supporting rollers 6 are flangeless. That is, they differ from the conventional type. They support two points on the lower part of the tread surface of each turning over wheel 5.
(13) Since the supporting rollers 6 are flangeless, the positions of the turning over wheels 5 in the direction Y1, in which direction the metal flask is transported (see FIG. 1) are not set by flanges. Thus by the present invention two pairs of side rollers 10 abut the side surfaces of each of the turning over wheels 5 as in FIGS. 1 and 2 to prevent the turning over wheels 5 from moving in the direction Y1, in which direction the metal flask is transported. Here, the movement in the direction Y1, in which direction the metal flask is transported, means both a movement in the direction Y1 and a movement in the reverse direction of the direction Y1. The side rollers 10 are located at the inner sides of the supporting rollers 6 (see FIG. 2). They are located outside the turning over wheels 5 in FIG. 1 (there are two pairs, thus in total four rollers. The rollers on the reverse side are omitted). By this configuration any movement of the turning over wheels 5 is prevented in the direction Y1, in which direction the metal flask is transported. Further, when a metal flask is transported at a high speed, the turning over wheels 5 are definitely prevented from moving downstream.
(14) FIG. 3 is an enlarged side view of one of the side rollers 10. As shown, the side roller 10 is attached so as to be inclined by means of a bracket 15. The side rollers 10 rotate when the turning over wheels 5 rotate either in the normal direction or in the reverse direction. The surfaces of the side rollers 10 are formed as arcs with a large radius R. They contact the side surfaces of the turning over wheels 5 at respective points. If the supporting rollers were flanged types, the flanges would rotate at a speed that differs from that of the turning over wheels 5 even when the supporting rollers rotate. Thus they would rub against each other to cause wear. However, the supporting rollers 6 are configured as flangeless to prevent differential movements of the side rollers 10 and the turning over wheels 5. No flanges of the supporting rollers contact the turning over wheels 5. Further, the side rollers 10 contact the turning over wheels 5 at respective points. Thus they are prevented from rubbing against each other. By this configuration wear caused by rubbing against each other can be prevented.
(15) On the upper part of the turning over wheel 5 a driving roller 9 is provided. One end of a bracket 16 for the driving roller 9 is pivotally supported by a pin 7. The other end of it is propelled by a spring 8 toward the tread surface of the turning over wheel 5. Thus the driving roller 9 is always pressed against the tread surface of the turning over wheel 5 so as to rotate the turning over wheel 5 in a normal or reverse direction. In this embodiment, the driving roller 9 is provided on the upper part of only one turning over wheel 5. However, the driving rollers 9 can be provided on the upper parts of both turning over wheels 5.
(16) The turning over roller conveyor 4 is fixed to the turning over wheels 5. Thus, when the turning over wheels 5 are turned over by means of the driving roller 9, the turning over roller conveyor 4, on which the metal flask 3 is mounted, is turned over so as to turn the metal flask 3 upside down.
(17) On the outer surface of the supporting roller 6 (see FIG. 2), a scraper 11 for cleaning the tread surface of the turning over wheel 5 is provided at an angle of 45 to the vertical plane. As in FIG. 2, the scraper 11 for cleaning the tread surface is formed by housing a rectangular scraper 14 and a spring 12 for pressing the scraper in a rectangular bracket 13 that is made of a rectangular pipe. The rectangular scraper 14 is always pressed against the tread surface of the turning over wheel 5 by means of the spring 12, to clean the tread surface. Because of this configuration, foreign matter that adheres to the tread surface of the turning over wheel 5 can be removed without the frequent maintenance that was conventionally carried out. Thus the wear of the turning over wheels 5 and the supporting rollers 6 can be reduced in this embodiment the scraper 11 for cleaning the tread surface is disposed at an angle of 45 to the vertical plane. But that angle can be changed at need. The scraper 11 for cleaning the tread surface is described as housing the rectangular scraper 14 in the rectangular bracket 13. But the shapes of the bracket and the scraper are not limited to a rectangular shape, but may be any practical shapes. The bracket is not necessarily made of a rectangular pipe.
(18) Now, with reference to FIGS. 4 and 5, a device 1a for turning over the molds is discussed. By the device 1a localized wear of the turning over wheel 5 can be prevented by adjusting the force to press the driving roller 9 against the turning over wheel 5.
(19) The driving roller 9 rotates in the normal direction and in the reverse direction by means of a motor 9a. One end of a bracket 9b for the driving roller 9 is pivotally attached to a frame 1b by means of a pin 7. The other end of the bracket 9b is attached to the frame 1b through an air cushion 8a. Thus by adjusting the inner pressure of the air cushion 8a the pressing force is changed. Thus the force of the driving roller 9 to press against the tread surface of the turning over wheel 5 can be discretionarily set. By the present embodiment, as in FIG. 5, a precisely acting reducing valve 20 is provided to the system of the pneumatic piping to the air cushion 8a so that the force for pressing by the air cushion 8a can be precisely adjusted. Incidentally, the reference number 21 denotes a filter that is provided to the system of the pneumatic piping. The reference number 22 denotes a residual pressure release valve. That is, compressed air from a source of compressed air (not shown) is depressurized by means of the reducing valve 20 and supplied to the air cushion 8a.
(20) As in FIG. 6, the driving roller 9 is formed as follows: Special rubber 9d (rubber having a high elastic modulus, a high friction factor, and a high resistance to friction, such as polyurethane rubber) is burned in a metal base 9c to adhere to it. If the force by the driving roller 9 to press were too strong, the rubber 9d that has been burned in the metal base 9 would disadvantageously exfoliate. On the contrary, if the force were too weak, the driving roller 9 would slip when accelerating or decelerating or stopping, so that the turning over wheel 5 would disadvantageously suffer from localized friction, to cause wear. However by the present embodiment, the driving roller 9 is configured to press against the turning over wheel 5 by means of the air cushion 8a. Further, the pressing force of the air cushion 8a can be precisely adjusted. Thus the driving roller 9 always drives the turning over wheel 5 at a stable force. Thus conventional defects, such as the exfoliating of the special rubber 9d or localized wear of the turning over wheel 5, can be prevented.
(21) As in FIG. 7, the surface of the turning over wheel 5 that contacts the supporting rollers 6 is made of a replaceable liner 5a that can be attached from the side by means of a bolt 18. As in FIG. 4, the liner 5a is divided into arc-shaped parts (the reference number 19 in FIG. 4 denotes the divided surface). Thus, if localized wear occurs, no turning over wheel 5 needs to be replaced as a whole. While the metal flask 3 is mounted on it, only the liner 5a can be replaced. Thus when localized wear occurs in the turning over wheel 5, only the liner 5a, on which the localized wear occurs, needs to be replaced to repair the turning over wheel 5.
(22) As discussed above, by the device for turning over the molds of the present invention, even when the speed to transport a metal flask or the speed of turning over becomes high because of a shorter cycle time, need for new turning over wheels 5 or new supporting rollers 6 can be advantageously reduced.
(23) The reference numbers used in the present specification and the drawings are as follows:
(24) 1,1a the device for turning over the molds
(25) 1b the frame
(26) 2 the conveyor with stationary rollers
(27) 3 the metal flask
(28) 4 the turning over roller conveyor
(29) 4a the roller with a flange
(30) 5 the turning over wheels
(31) 5a the liner
(32) 6 the supporting rollers
(33) 7 the pin
(34) 8 the spring
(35) 8a the air cushion
(36) 9 the driving roller
(37) 9a the motor
(38) 9b the bracket
(39) 9c the base
(40) 9d the special rubber
(41) 10 the side roller
(42) 11 the scraper for cleaning the tread surface
(43) 12 the spring
(44) 13 the rectangular bracket
(45) 14 the rectangular scraper
(46) 15 the bracket
(47) 16 the bracket
(48) 18 the bolt
(49) 19 the divided surface
(50) 20 the reducing valve
(51) 21 the filter
(52) 22 the residual pressure release valve
(53) 101 the device for turning over the molds
(54) 102 the conveyor with stationary rollers
(55) 103 the metal flask
(56) 104 the turning over roller conveyor
(57) 105 the turning over wheels
(58) 106 the supporting rollers with flanges
(59) 109 the driving roller
(60) 111 the scraper for cleaning the tread surface
