JP2011115848A - Feeder of casting sand for sampling, sand logging device, and method for supplying casting sand for sampling - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent delay in cycle time of molding/sand processing line equipment. <P>SOLUTION: The feeder of casting sand for sampling supplies casting sand to a sand testing means 108 by taking out casting sand for sampling from a casting sand transporting means 104 that transports casting sand to be used for cast molding. The feeder includes: a sand logging device 121 that has a sand feeding port 101c in one end and a sand discharging port 101d in the other end; a sand charging shoot 107 whose one end communicates with the sand discharging port of the sand logging device and the other end communicates with the sand testing means; an opening/closing gate 112 installed on the sand charging shoot; and a sand temperature measuring means that is installed in the sand charging shoot and that measures temperature of the casting sand collected on a gate board 112a in the opening/closing gate. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention provides a sampling foundry sand supply device, a sand cutting device, and a sampling foundry sand for supplying the foundry sand sampled to a sand tester or the like when inspecting the properties of the foundry sand used for mold molding. It relates to a supply method.

  Conventionally, it has been publicly known that an operator manually supplies a sand sand sample used for mold making to a sand tester (see, for example, Patent Document 1). It is also known to measure the sand temperature, CB value (compactability value), moisture, air permeability, and compressive strength of the supplied foundry sand by the sand tester (see, for example, Patent Document 1). .

  Further, as a sand cutting device used when feeding the foundry sand for sampling to the sand testing machine, conventionally, a part of the kneaded sand which has been kneaded or being kneaded is put into a horizontal cylindrical hopper, A sand cutting device is known in which sand kneaded with a screw-type sand unpacking device is taken out while pressing the kneaded sand charged into the sand with a pressing plate connected to an electric cylinder. For example, see Patent Document 2).

Japanese Utility Model Publication No. 6-61346 JP 2003-205344 A

  However, when sampling sand is taken out from the foundry sand that is being transported and supplied to the sand tester while the molding and sand processing line equipment is in operation, the burden on the operator is inevitable. There is a problem that it becomes excessive. Further, the sand tester described in Patent Document 1 measures all the sand temperature, CB value (compactability value), moisture, air permeability, and compressive strength of the supplied foundry sand. There is a problem that it takes time to delay the cycle time of the molding / sand processing line equipment.

  Moreover, since the screw of the sand loosening device described in Patent Document 2 is a coil-type hollow spring, when the spring length becomes long, the spring meanders when the spring rotates and contacts the inner surface of the horizontal cylindrical hopper, There is a problem of causing wear. Further, when the coil-type hollow spring is used as a screw, there is a problem that the sampled sand casts in the gap between the springs.

  As described above, when inspecting the properties of foundry sand used for mold making, sampling foundry sand may not be properly supplied to the sand testing means.

  An object of the present invention is to provide a sampling foundry sand supply device, a sand cutting device, and a sampling foundry sand supply method capable of appropriately supplying the sampling foundry sand to the sand testing means.

  More specifically, the object of the present invention is to allow sampling sand for sampling to be taken out by a mechanical device from the foundry sand being conveyed during operation of the molding and sand processing line equipment and supplied to the sand tester. An object of the present invention is to provide a sampling sand supply apparatus and method which can prevent delay in cycle time of the molding / sand processing line equipment.

  In addition, the object of the present invention is made in view of the above problems, and the sampling foundry sand that can increase the length of the screw and eliminate the accumulation of the sampled foundry sand on the screw. It is providing a sand cutting device.

  In order to achieve the above-mentioned object, the sampling sand supply apparatus for sampling according to the present invention is a sampling which takes out the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold making and supplies it to the sand testing means. Cast sand supply device for sand having a sand supply port at one end and a sand discharge port at the other end, one end communicating with the sand discharge port of the sand cut device and the other end being a sand test A sand throwing chute that communicates with the means, an openable gate attached to the sand throwing chute, and a sand that is attached to the sand throwing chute and measures the temperature of the foundry sand stored on the gate plate in the openable gate Temperature measuring means, and the sand cutting device includes an outer cylinder body provided with the sand supply port at one end and the sand discharge port at the other end, and the outer cylinder body. An inner cylinder fixed to the inner surface, and a rotatable and solid screw penetrating the inside of the inner cylinder and having one end inserted into the foundry sand conveying means and the other end connected to the driving means And have.

  The sand cutting device according to the present invention is a sand cutting device for sampling and feeding the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold making, and supplying the sand to the sand testing means. An outer cylinder having a mouth and a sand discharge port at the other end, an inner cylinder fixed to the inner surface of the outer cylinder, the inside of the inner cylinder passing through, and one end of the casting sand transport A rotatable solid screw inserted into the means and connected at the other end to the drive means.

  The sampling foundry sand supply method according to the present invention includes a sand cutting device having a sand supply port at one end and a sand discharge port at the other end, and one end communicating with the sand discharge port of the sand cutting device. A sand throwing chute with the other end communicating with the sand testing means; an open / close gate attached to the sand throwing chute; and a casting sand attached to the sand throwing chute and stored on the gate plate in the openable gate. A sand temperature measuring means for measuring the temperature, and a sampling sand feeding device for sampling, and the sand testing means by sampling the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold molding. A method for supplying the foundry sand for sampling, wherein the sand cutting device is normally operated in a state in which the openable gate is open, A first supply step for sampling and removing the foundry sand from the conveying means and supplying it to the sand testing means via the sand input chute; and the openable gate is closed during the first supply step, and the gate in the openable gate A step of storing foundry sand on the plate, a step of measuring the temperature of the foundry sand stored on the gate plate by the sand temperature measuring means, and opening the openable gate to store the foundry sand on the gate plate A second supply step of supplying sand to the sand test means, and a step of returning the foundry sand remaining in the sand cutout device to the foundry sand transport means by reversely operating the sand cutout device; Have

  The present invention includes a sand cutting device having a sand supply port at one end and a sand discharge port at the other end, and a sand injection device having one end communicating with the sand discharge port of the sand cutting device and the other end communicating with the sand testing means. A chute, an openable gate attached to the sand throwing chute, and a sand temperature measuring means for measuring the temperature of the foundry sand attached to the sand throwing chute and stored on the gate plate in the openable gate. Since the molding molding / sand processing line equipment is in operation, the sampling molding sand can be taken out from the casting sand transported by the mechanical device and supplied to the sand tester and the molding / sand processing can be performed. There are various effects such as prevention of delay in cycle time of line equipment.

  The present invention also includes an outer cylinder having a sand supply port at one end and a sand discharge port at the other end, an inner cylinder fixed to the inner surface of the outer cylinder, and penetrating the inside of the inner cylinder. And a rotatable and solid screw having one end inserted into the foundry sand conveying means and the other end connected to the driving means, so that the length of the screw is increased. There are various effects such as being able to eliminate the accumulation of the sampled casting sand on the screw.

It is a figure of 1st Embodiment and is a front view which shows the supply apparatus of the foundry sand for sampling to which this invention is applied. It is the A section enlarged detail drawing of FIG. It is a BB arrow line view of FIG. It is a right view of FIG. 1, and is a figure which shows a belt conveyor and its upstream and downstream apparatus. It is the figure which removed the screw from the apparatus and showed only the screw, (A) is a front view, (B) is a left side view. It is detail drawing of the front-end | tip part of a screw. It is detail drawing of the front-end | tip part of a screw, Comprising: It is a figure for demonstrating the semicircle cross-sectional area of the semicircle-shaped groove part in a screw. It is a figure of 2nd Embodiment and is a front view which shows the supply apparatus of the foundry sand for sampling to which this invention is applied. It is a figure of 2nd Embodiment and is the A section enlarged detail drawing of FIG. It is a figure of 2nd Embodiment and is a BB arrow line view of FIG. It is a figure of 2nd Embodiment and is CC arrow line view of FIG. It is a figure of 2nd Embodiment, and is a right view of FIG. 8, and is a figure which shows a belt conveyor and its upstream and downstream apparatus.

  A sampling foundry sand supply apparatus and sand cutting apparatus to which the present invention is applied will be described below with reference to the drawings. First, as a first embodiment, a sampling foundry sand supply device 20 and a sand cutting device 21 will be described with reference to FIGS.

  As shown in FIG. 1, the sampling foundry sand supply device 20 is a sampling foundry sand supply device that samples the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold making and supplies it to the sand testing means. A sand cutting device 21 having a sand supply port at one end and a sand discharge port at the other end, one end communicating with the sand discharge port of the sand cutting device 21 and the other end being a sand test means (sand characteristics automatic And a sand throwing chute 7 communicating with the measuring device 8). The sand cutting device 21 has an outer cylinder 1, an inner cylinder 2, and a screw 3.

  Specifically, as shown in FIG. 1, the outer cylindrical body 1 includes a cylindrical portion 1 a and a casing portion 1 b. The outer cylinder 1 has a sand supply port 1c at one end and a sand discharge port 1d at the other end. And the inner cylinder 2 is fixed to the inner surface of the cylindrical part 1a in the outer cylinder 1 by fastening, and the inner cylinder 2 can be replaced when worn.

  A rotatable and solid screw 3 is disposed inside the inner cylinder 2, and the screw 3 penetrates the inside of the inner cylinder 2. One end of the screw 3 is inserted into a belt conveyor 4 as a foundry sand conveying means, and the other end is connected to a motor 5 as a driving means described later. The screw 3 is rotated by the operation of the motor 5. The material of the inner cylinder 2 and the screw 3 is ultra high molecular weight polyethylene (for example, “Saxin New Light” manufactured by Sakushin Kogyo Co., Ltd.). In the present embodiment, the inner cylinder 2 has an inner diameter of 78 mm, and the screw 3 has a lead outer diameter of 72 mm (excluding the tip, which will be described later). The inner diameter of the inner cylinder 2 and the screw The gap with the lead outer diameter of 3 is 3 mm on one side.

  The casing portion 1 b in the outer cylinder 1 is surrounded by a support 6. A cylindrical portion 1 a of the outer cylinder 1 is fastened and fixed to one end of the support 6, and the motor 5 is fastened and fixed to the other end of the support 6. A sand throwing chute 7 is connected to the lower end of the support 6, and a sand characteristic automatic measuring device 8 as sand testing means is connected to the lower end of the sand throwing chute 7. The sand discharge port 1d of the outer cylinder 1 and the sand characteristic automatic measuring device 8 are communicated with each other via the sand throwing chute 7.

  As shown in FIGS. 2 and 3, a plurality of (four in this embodiment) sand loosening members 9 for loosening the foundry sand S (see FIG. 1) are provided on the outer periphery of the other end of the screw 3. The sand loosening member 9 and the shaft coupling 10 are accommodated inside the casing portion 1b of the outer cylinder 1.

  In addition, a plurality of (three in this embodiment) collision members 11 that collide with the foundry sand S to be discharged are disposed at the sand discharge port 1d of the outer cylinder 1, and the collision members 11 are arranged in the outer cylinder. The body 1 is fastened and fixed to the casing portion 1b. In this embodiment, a round bar is used as the collision member 11.

  The operation of the apparatus configured as described above will be described. First, when the motor 5 is normally operated during the operation of the belt conveyor 4, that is, while the foundry sand S is being conveyed, the screw 3 rotates in the direction of the arrow Y1 in FIG. Then, the foundry sand S is conveyed from the sand supply port 1c of the outer cylinder 1 by the screw 3. Then, the conveyed foundry sand S collides with the sand unraveling member 9 that rotates together with the screw 3 in the casing portion 1 b of the outer cylinder 1 and is unraveled. Thereafter, the foundry sand S collides with the collision member 11 disposed at the sand discharge port 1d of the outer cylindrical body 1, where it is further loosened and discharged from the sand discharge port 1d. Then, the discharged foundry sand S is supplied into the sand characteristic automatic measuring device 8 through the sand charging chute 7.

  Thereafter, when the motor 5 is reversely operated while the belt conveyor 4 is operating or stopped, that is, while the molding sand S is being conveyed or stopped, the screw 3 is rotated in the direction of the arrow Y2 in FIG. Then, the foundry sand S remaining in the screw 3 and the inner cylindrical body 2 is conveyed toward the sand supply port 1c of the outer cylindrical body 1, discharged from the sand supply port 1c, and returned onto the belt conveyor 4. . In the present embodiment, green sand is used as the foundry sand S.

  In addition, when the foundry sand S is supplied, the sand characteristic automatic measuring device 8 measures the moisture, CB value (compactability value), compressive strength, air permeability, and sand temperature of the foundry sand S.

  The belt conveyor 4 in this embodiment is a belt conveyor that is disposed above the mold making machine 12 (see FIG. 4) and supplies the foundry sand S to the mold making machine 12. Here, this point Will be described in detail. FIG. 4 is a right side view of FIG. 1 and shows the belt conveyor 4 and upstream and downstream devices. As shown in FIG. 4, the belt conveyor 4 is disposed above the mold making machine 12 and is assembled on a mount 13. A sand storage device 14 for storing foundry sand S (kneaded sand that has been kneaded with a foundry sand kneader) is disposed above the belt conveyor 4, and a support 14 a of the sand storage device 14 is a base 13. It is assembled on the top. Further, the foundry sand S conveyed by the belt conveyor 4 is supplied to the mold making machine 12 through a chute 15 supported by the gantry 13.

  The mold making machine 12 in this embodiment is an upper frame / lower frame (not shown) frame making machine, and each time one frame is made, the belt conveyor 4 is operated to form one frame of foundry sand. S is supplied to the mold making machine 12. In the present embodiment, every time the casting sand S for the lower frame is conveyed on the belt conveyor 4, the casting sand S is sampled and extracted from the belt conveyor 4 as described above to the automatic sand property measuring device 8. Supply.

  Conventionally, a belt conveyor 4 that periodically conveys the foundry sand S at a predetermined timing as described above (a belt conveyor that is disposed above the mold making machine 12 and supplies the foundry sand S to the mold making machine 12). While it was difficult to sample the foundry sand S from the belt conveyor 4 during the conveyance of 4), the present invention has an advantage that it can be applied to such a case.

  Next, details of the screw 3 will be described in detail. FIG. 5 is a view showing only the screw 3 with the screw 3 removed from the apparatus, (A) is a front view, and (B) is a left side view. As shown in FIG. 5A, the screw 3 has a plurality of leads 3a formed continuously. A semicircular groove 3b is continuously formed between the leads 3a. Thus, it is preferable that the groove formed continuously between the leads 3a has a semicircular shape because the casting sand S hardly adheres to the groove.

  The screw 3 has a tapered shape with a tapered tip, which will be described in detail. FIG. 6 is a detailed view of the tip of the screw 3. In this embodiment, the dimension X1 is φ72 mm, X2 is φ70 mm, and X3 is 65.5 mm. That is, a taper shape is formed from the tip end surface of the screw 3 to a position of 65.5 mm, and the lead outer diameter is processed to φ72 mm after the position of 65.5 mm. Yes. If the tip of the screw 3 is tapered in this way, a wide gap can be secured between the tip of the screw 3 and the tip of the inner surface of the inner cylinder 2. This is preferable because there is an effect that it is possible to prevent the foundry sand S from being caught in the gap between the tip portion and the inner surface tip of the inner cylinder 2. If the foundry sand S is caught in the gap, there may be a problem that the apparatus vibrates or the screw 3 or the inner cylinder 2 is worn early.

  Further, the screw 3 has a semicircular cross-sectional area of the earliest semicircular groove in the screw 3 that is smaller than a semicircular cross-sectional area of the second and subsequent semicircular grooves, which will be described in detail. For easy understanding, the earliest semicircular groove is denoted by reference numeral 300, and the second and subsequent semicircular grooves are denoted by reference numeral 301. As shown in FIG. 7, in the present embodiment, the semicircular cross-sectional area 302 of the earliest semicircular groove 300 in the screw 3 is formed by making the tip of the screw 3 taper as described above. However, it is smaller than the semicircular cross-sectional area 303 of the semicircular groove 301 after the second stage. With such a configuration, the foundry sand S that has entered the earliest semicircular groove 300 first is conveyed while being accommodated without overflowing into the second and subsequent semicircular grooves 301. Since there is an effect that the foundry sand S is not compressed in the middle, it is preferable. If the foundry sand S is compressed during the conveyance, there may be a problem that the sand property changes.

  The configuration in which the semicircular cross-sectional area 302 of the earliest semicircular groove 300 in the screw 3 is made smaller than the semicircular cross-sectional area 303 of the second and subsequent semicircular grooves 301 is that the tip of the screw 3 described above is The configuration is not limited to a tapered shape, and another configuration may be used.

  The screw 3 is made of ultra high molecular weight polyethylene as described above, and a through hole is formed in the central portion of the screw 3 made of the ultra high molecular weight polyethylene, and a rod-shaped cored bar 3c (material) is formed in the through hole. Is fitted with SUS304 (see FIG. 5). The metal core 3c and the screw 3 are bonded with an adhesive, and the metal core 3c is fixed to the screw 3 with a taper pin 3d. As described above, it is preferable to fit the core 3c to the screw 3 because the vibration of the screw when the screw 3 rotates can be suppressed. However, when the total length of the screw 3 is short, the core 3c is There is no need.

  Since the screw 3 constituting the sand cutting device 21 to which the present invention is applied is not a coil-type hollow spring but a solid screw, even when the screw 3 is lengthened, the screw 3 is rotated. The screw 3 does not meander. For this reason, the length of the screw 3 can be lengthened and can be used for transporting the casting sand S over a long distance. Further, if the screw 3 is not a coil-type hollow spring but a solid screw, the spring gap itself does not exist, so that the accumulation of the foundry sand S on the screw 3 can be eliminated.

  Moreover, in the sand cutting device 21 to which the present invention is applied, as described above, since the material of the inner cylinder 2 and the screw 3 is ultrahigh molecular weight polyethylene, the adhesion of sand to the inner cylinder 2 and the screw 3 is suppressed. There is an effect that can be. When sand adheres to the inner cylinder 2 and the screw 3, when the foundry sand S is conveyed into the sand characteristic automatic measuring device 8, the adhered sand is separated from the inner cylinder 2 and the screw 3 during the conveyance. In some cases, there is a problem in that the sand property changes due to mixing with the foundry sand S being conveyed.

  Further, in the sand cutting device 21 to which the present invention is applied, as described above, since the sand unraveling member 9 for loosening the foundry sand S is fixed to the other end of the screw 3, the foundry sand S conveyed by the screw 3 is used. Even if sand lumps are contained in the sand, the sand dams can be loosened and supplied into the sand characteristic automatic measuring device 8. Moreover, in the sand cutting device 21 to which the present invention is applied, as described above, the collision member 11 that collides with the foundry sand S to be discharged is disposed at the sand discharge port 1d of the outer cylindrical body 1, and thus the foundry sand. The sand lumps contained in S can be further loosened here. In this embodiment, both the sand loosening member 9 and the collision member 11 are used. However, the present invention is not limited to this, and either the sand loosening member 9 or the collision member 11 may be used. Good. However, it is preferable to use both the sand loosening member 9 and the collision member 11 because the effect of loosening the sand dust is higher.

  In addition, in this embodiment, although the belt conveyor 4 was shown as a foundry sand conveyance means, it is not limited to this, For example, a foundry sand kneader is mentioned as a foundry sand conveyance means.

  In the present embodiment, the sand discharge port 1d of the outer cylinder 1 and the sand characteristic automatic measuring device 8 are communicated with each other via the sand throwing chute 7, but the present invention is not limited to this. The sand throwing chute 7 may be eliminated, and the sand discharge port 1d of the outer cylinder 1 and the sand characteristic automatic measuring device 8 may be directly communicated with each other.

  As described above, the sand cutting device 21 to which the present invention is applied is fixed to the outer cylinder 1 having the sand supply port 1c at one end and the sand discharge port 1d at the other end, and the inner surface of the outer cylinder 1. An inner cylinder 2 and a rotatable and solid screw which penetrates the inside of the inner cylinder 2 and has one end inserted into the foundry sand conveying means (belt conveyor 4) and the other end connected to the driving means. 3, and by having such a configuration, it is possible to increase the length of the screw and to eliminate the accumulation of sampled foundry sand on the screw.

  The sand cutting device 21 is also characterized by a structure in which the semicircular groove portions 300 and 301 are continuously formed between the leads of the screw 3, and the effect that the foundry sand S hardly adheres to the groove portions. And the accumulation of the sampled foundry sand on the screw 3 can be eliminated.

  Further, the sand cutting device 21 has a configuration in which the semicircular cross-sectional area 302 of the first semicircular groove 300 in the screw 3 is smaller than the semicircular cross-sectional area 303 of the semicircular groove 301 in the second and subsequent stages. Therefore, it is possible to obtain the effect that the molding sand S is not compressed, and the sand property is changed by compressing the molding sand S during the conveyance.

  The sand cutting device 21 is also characterized in that the tip of the screw 3 has a tapered shape, and the gap between the tip of the screw 3 and the tip of the inner surface of the inner cylinder 2 is widened. As a result, it is possible to prevent the foundry sand S from being caught in the gap between the tip of the screw 3 and the inner surface of the inner cylinder 2, and the device may vibrate or wear parts due to the biting. It is possible to prevent the occurrence of malfunctions.

  The sand cutting device 21 is also characterized in that the material of the inner cylinder 2 and the screw 3 is ultrahigh molecular weight polyethylene, and can suppress sand adhesion to the inner cylinder 2 and the screw 3. As a result, it is possible to prevent the occurrence of a problem that the sand property is changed due to separation of the adhering sand and mixing with the foundry sand being conveyed, which is a problem due to sand adhesion.

  The sand cutting device 21 and the sampling foundry sand supply device 20 using the sand cutting device 21 as described above can appropriately supply the sampling foundry sand to the sand testing means.

  Next, as a second embodiment, a sampling foundry sand supply device 120 and a sand cutting device 121 will be described with reference to FIGS. Here, as the sand cutting device 121 used in the sampling foundry sand supply device 120, a screw-type sand cutting device is used as in the first embodiment described above.

  As shown in FIG. 8, the sampling foundry sand supply device 120 is a sampling foundry sand supply device that samples the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold making and supplies it to the sand testing means. A sand cutting device 121 having a sand supply port at one end and a sand discharge port at the other end, one end communicating with the sand discharge port of the sand cutting device 121 and the other end being sand test means (sand characteristics automatic A sand throwing chute 107 communicating with the measuring device 108), an openable gate 112 attached to the sand throwing chute, and a casting sand attached to the sand throwing chute and stored on the gate plate in the openable gate 112 And a sand temperature measuring means (thermocouple 113) for measuring the temperature. The sand cutting device 121 includes an outer cylinder 101, an inner cylinder 102, and a screw 103.

  Specifically, as shown in FIG. 8, the outer cylinder 101 is composed of a cylindrical portion 101a and a casing portion 101b. The outer cylinder 101 has a sand supply port 101c at one end and a sand discharge port 101d at the other end. The inner cylinder 102 is fixed to the inner surface of the cylindrical portion 101a of the outer cylinder 101 by fastening, and the inner cylinder 102 can be replaced when worn.

  A rotatable and solid screw 103 is disposed inside the inner cylinder 102, and the screw 103 passes through the inner cylinder 102. One end of the screw 103 is inserted into a belt conveyor 104 as a foundry sand conveying means, and the other end is connected to a motor 105 as a driving means described later. The screw 103 is rotated by the operation of the motor 105. The material of the inner cylinder 102 and the screw 103 is ultra high molecular weight polyethylene (for example, “Saxin New Light” manufactured by Sakushin Kogyo Co., Ltd.).

  A plurality of leads 103a are continuously formed on the screw 103. A semicircular groove 103b is continuously formed between the leads 103a (see FIG. 9). Furthermore, the screw 103 has a tapered shape with a tapered tip (not shown). In the present embodiment, the inner diameter of the inner cylinder 2 is φ78 mm, and the outer diameter of the lead of the screw 103 is φ72 mm. The gap between the inner diameter of the inner cylinder 2 and the outer diameter of the lead of the screw 103 is 3 mm on one side. Has been.

  The screw 103 has the same configuration as the screw 3 described in detail with reference to FIGS. 5 to 7 described above, for example, and detailed description thereof is omitted here.

  The casing 101 b in the outer cylinder 101 is surrounded by a support 106. A cylindrical portion 101 a of the outer cylinder 101 is fastened and fixed to one end of the support 106, and the motor 105 is fastened and fixed to the other end of the support 106.

  Further, as shown in FIGS. 9 and 10, a plurality of (four in this embodiment) sand loosening members 109 for loosening the foundry sand S (see FIG. 8) are provided on the outer periphery of the other end of the screw 103. The sand loosening member 109 and the shaft coupling 110 are accommodated inside the casing portion 101b of the outer cylindrical body 101.

  A plurality of (three in this embodiment) collision members 111 that collide with the foundry sand S to be discharged are arranged at the sand discharge port 101d of the outer cylinder 101, and the collision members 111 are arranged in the outer cylinder. The body 101 is fastened and fixed to the casing portion 101b. In this embodiment, a round bar is used as the collision member 111.

  In addition, a sand throwing chute 107 is connected to the lower end of the support 106 in the screw type sand cutting device 121 constructed as described above, and the sand throwing chute 107 has a sand characteristic automatic as a sand test means at the lower end. A measuring device 108 is connected. The sand discharge port 101d of the outer cylinder 101 and the sand characteristic automatic measuring device 108 are communicated with each other through the sand throwing chute 107.

  An openable gate 112 is attached to the sand throwing chute 107. As shown in FIG. 11, the openable gate 112 includes a gate plate 112a, a rotating cylinder 112b that moves the gate plate 112a to a horizontal state or a vertical state, and a connection that connects the gate plate 112a and the rotating cylinder 112b. And the member 112c. The gate plate 112 a is disposed inside the sand throwing chute 107, and the rotating cylinder 112 b is disposed outside the sand throwing chute 107.

  A thermocouple 113 as a sand temperature measuring means for measuring the temperature of the foundry sand S stored on the gate plate 112a is attached above the gate plate 112a in the horizontal state of the sand throwing chute 107. . In addition, a photoelectric sensor 108a (see FIG. 8) as a foundry sand detection means is attached to the inside of the sand characteristic automatic measuring device 108.

  The operation of the sampling foundry sand supply apparatus 120 configured as described above, that is, a method for supplying the sampling foundry sand using the sampling foundry sand supply apparatus 120 will be described. First, when the motor 105 is normally operated while the belt conveyor 104 is operating, that is, while the foundry sand S is being conveyed, with the openable gate 112 being opened, the screw 103 rotates in the direction of the arrow Y1 in FIG. To do. Then, the foundry sand S is conveyed from the sand supply port 101 c of the outer cylinder 101 by the screw 103. Then, the conveyed foundry sand S collides with the sand unraveling member 109 that rotates together with the screw 103 in the casing portion 101 b of the outer cylinder 101 and is unraveled. Thereafter, the foundry sand S collides with a collision member 111 disposed at the sand discharge port 101d of the outer cylinder 101, where it is further loosened and discharged from the sand discharge port 101d. The discharged foundry sand S is supplied into the sand characteristic automatic measuring device 108 through the sand throwing chute 107 (first supply step).

  In the first supply step, when it is detected by the ON signal of the photoelectric sensor 108a that the predetermined amount of foundry sand S has been supplied into the sand characteristic automatic measuring device 108, the openable gate 112 is closed and the gate is closed. The plate 112a is set in a horizontal state, and the foundry sand S is collected on the gate plate 112a. The normal operation of the motor 105 is stopped after a predetermined time from the detection of the ON signal of the photoelectric sensor 108a. The predetermined time is measured by a timer.

  Next, the temperature of the foundry sand S collected on the gate plate 112a is measured by the thermocouple 113. In parallel with the temperature measurement step of the foundry sand S, the sand property automatic measuring device 108 measures the CB value (compactability value) and moisture of the foundry sand S.

  When the CB value (compactability value) and moisture of the foundry sand S are measured, the foundry sand S in the sand characteristic automatic measuring device 108 is discarded and collected by a foundry sand collecting means (not shown). Thereafter, the openable gate 112 is opened to bring the gate plate 112a into a vertical state, and the foundry sand S stored on the gate plate 112a is supplied to the sand characteristic automatic measuring device 108 (second supply step). Here, confirmation that the foundry sand S has been supplied into the sand characteristic automatic measuring device 108 is performed by detecting an ON signal of the photoelectric sensor 108a.

  Next, the sand characteristic automatic measuring device 108 measures the air permeability and compressive strength of the foundry sand S. When the air permeability and compressive strength of the foundry sand S are measured, the foundry sand S in the automatic sand property measuring device 108 is discarded and collected by the foundry sand collecting means.

  As described above, the normal operation of the motor 105 is stopped after a predetermined time from the detection of the ON signal of the photoelectric sensor 108a. After the stop, the motor 105 is reversely operated. When the motor 105 is reversely operated, the screw 103 rotates in the direction of the arrow Y2 in FIG. Then, the foundry sand S remaining in the screw 103 and the inner cylinder 102 is conveyed toward the sand supply port 101c of the outer cylinder 101, and is discharged from the sand supply port 101c and returned onto the belt conveyor 104. . In the present embodiment, green sand is used as the foundry sand S.

  The belt conveyor 104 in the present embodiment is a belt conveyor that is disposed above the mold making machine 114 (see FIG. 12) and supplies the foundry sand S to the mold making machine 114. Will be described in detail. FIG. 12 is a right side view of FIG. 8, showing the belt conveyor 104 and its upstream and downstream devices. As shown in FIG. 12, the belt conveyor 104 is disposed above the mold making machine 114 and is assembled on a pedestal 115. A sand storage device 116 for storing foundry sand S (kneaded sand that has been sand kneaded by a foundry sand kneader) is disposed above the belt conveyor 104, and a column 116 a of the sand storage device 116 is a frame 115. It is assembled on the top. The foundry sand S transported by the belt conveyor 104 is supplied to the mold making machine 114 via a chute 117 supported by a gantry 115.

  The mold making machine 114 in this embodiment is an upper frame / lower frame (not shown) frame making machine. Each time one frame is made, the belt conveyor 104 is operated to form one frame of foundry sand. S is supplied to the mold making machine 114. In the present embodiment, the sand sand S is sampled from the belt conveyor 104 and transferred to the sand property automatic measuring device 108 as described above each time the lower sand foundry sand S is conveyed on the belt conveyor 104. Supply.

  Conventionally, a belt conveyor 104 (which is disposed above the mold making machine 114 and supplies the foundry sand S to the mold making machine 114) that regularly conveys the foundry sand S at a predetermined timing as described above. 104) It has been difficult to sample the foundry sand S from the belt conveyor 104 during the conveyance, but the present invention has an advantage that it can be applied to such a case.

  In the present invention, during the operation of the molding / sand processing line equipment, the sampling foundry sand can be taken out from the transported foundry sand S by a mechanical device and supplied to the sand characteristic automatic measuring device 108. The manual work of the person can be eliminated.

  Further, in the present invention, the process of supplying the foundry sand S to the sand property automatic measuring device 108 is divided into two times. The temperature of the foundry sand S collected on the gate plate 112a is measured by the thermocouple 113. Thereby, in parallel with the temperature measurement process of the foundry sand S, the sand characteristic automatic measuring device 108 can perform various measurements of the foundry sand S (in the above-described embodiment, the measurement of the CB value and moisture). Time can be shortened. Thereby, the delay of the cycle time of a molding and sand treatment line equipment can be prevented.

  In the present embodiment, the belt conveyor 104 is shown as the foundry sand conveying means. However, the present invention is not limited to this, and the foundry sand conveying means includes, for example, a foundry sand kneader.

  Further, in this embodiment, every time the casting sand S for the lower frame is conveyed on the belt conveyor 104, the foundry sand S is sampled from the belt conveyor 104 and supplied to the sand characteristic automatic measuring device 108. However, the present invention is not limited to this, and every time sand sand S for upper frame is conveyed on the belt conveyor 104, the sand sand S is sampled and extracted from the belt conveyor 104. You may make it supply to the measuring device 108. FIG. Moreover, regardless of the casting sand S for the lower frame and the upper frame, it is not limited to performing each time during the conveyance by the belt conveyor 104, and is performed at a rate of once for several conveyances. Also good.

  Furthermore, in this embodiment, after the foundry sand S is supplied to the sand property automatic measuring device 108 in the second supply step, the sand property automatic measuring device 108 measures the air permeability and compressive strength of the foundry sand S. However, the present invention is not limited to this, and the measurement of the air permeability and compressive strength of the foundry sand S may be omitted. In this case, after the CB value and moisture of the foundry sand S are measured, the openable gate 112 is opened to bring the gate plate 112a into a vertical state, and the foundry sand S stored on the gate plate 112a is converted into the sand characteristics. Supply to the automatic measuring device 108 (second supply step). Thereafter, the foundry sand S in the sand characteristic automatic measuring device 108 is discarded at a time and collected by the foundry sand collecting means.

  As described above, the sampling foundry sand supply device 120 to which the present invention is applied includes the sand cutting device 121 having the sand supply port 101c at one end and the sand discharge port 101d at the other end, and the sand of the sand cutting device 121 at one end. A sand throwing chute 107 communicating with the discharge port 101d and the other end communicating with the sand characteristic automatic measuring device 108, an openable gate 112 attached to the sand throwing chute 107, a sand throwing chute 107 and an open / close type It is characterized in that it comprises a thermocouple 113 for measuring the temperature of the foundry sand stored on the gate plate 112a in the gate 112. By providing such a configuration, molding / sand treatment line equipment is provided. During operation, the sampling foundry sand is taken out from the foundry sand transported by the machine and supplied to the sand tester. It is possible to prevent the molding-delay cycle time of sand processing line equipment it is.

  In addition, when the open / close gate 112 is closed, the sampling foundry sand supply device 120 collects the foundry sand on the gate plate 112a of the open / close gate 112, so that the thermocouple 113 stores it on the gate plate 112a. The temperature of the foundry sand is measured, and when the openable gate 112 is opened, the foundry sand from the sand cutting device 121 or the foundry sand stored on the gate plate 112a is supplied to the sand characteristic automatic measuring device 108. Also, by having such a configuration, it is possible to prevent a delay in cycle time of the molding / sand processing line facility.

  Similarly to the sand cutting device 21, the sand cutting device 121 to which the present invention is applied includes an outer cylinder 101 having a sand supply port 101 c at one end and a sand discharge port 101 d at the other end, and an outer cylinder 101. An inner cylinder 102 fixed to the inner surface, and the inside cylinder 102 is penetrated, and one end is inserted into a belt conveyor 104 as a foundry sand conveying means and the other end is connected to a driving means. And having a solid screw 103. By having such a configuration, the length of the screw can be increased and the accumulated sand of the sampled foundry sand on the screw can be eliminated. be able to.

  In addition, the sand cutting device 121 has a configuration in which semicircular groove portions are continuously formed between the leads of the screw 103 in the same manner as the screw 3 of the sand cutting device 21, or the earliest semicircular groove portion in the screw 103. The semicircular cross-sectional area is smaller than the semicircular cross-sectional area of the second and subsequent semicircular groove portions, and the screw 103 has a tapered tapered shape at the tip thereof. The same effect as that of the sand cut-out device 21 can be exhibited.

  The sand cutting device 121 is also characterized in that the material of the inner cylinder 102 and the screw 103 is ultra high molecular weight polyethylene, and can suppress sand adhesion to the inner cylinder 102 and the screw 103. As a result, it is possible to prevent the occurrence of a problem that the sand property is changed due to separation of the adhering sand and mixing with the foundry sand being conveyed, which is a problem due to sand adhesion.

The sampling foundry sand supply method to which the present invention is applied is obtained by sampling the foundry sand from the foundry sand transporting means for transporting the foundry sand used for mold molding using the sampling foundry sand supply device 120 described above. A method of supplying the foundry sand for sampling to be supplied to the sand testing means (sand characteristic automatic measuring device 108). A first supply step for sampling and taking out the foundry sand and supplying it to the sand testing means via the sand injection chute 107, and the openable gate 112 is closed during the first supply step, and the gate plate 112a on the openable gate 112 is A process of storing the foundry sand on the gate plate, and a process for measuring the temperature of the foundry sand stored on the gate plate 112a with a sand temperature measuring means (thermocouple 113). A second supply step of opening the openable gate 112 and supplying the sand found on the gate plate 112a to the sand testing means, and by reversely operating the sand cutting device 121, the sand cutting device 121 And having a step of returning the foundry sand remaining inside to the foundry sand conveying means. By having such a configuration, the foundry sand is conveyed during operation of the molding and sand processing line equipment. Sampling foundry sand can be taken out from the foundry sand by a mechanical device and supplied to a sand tester, and delay in cycle time of the molding / sand processing line facility can be prevented.
The sand cutting device 121 and the sampling foundry sand supply device 120 as described above and the method for supplying the sampling foundry sand using the same can appropriately supply the sampling foundry sand to the sand testing means.

DESCRIPTION OF SYMBOLS 1 Outer cylinder 1c Sand supply port 1d Sand discharge port 2 Inner cylinder 3 Screw 3a Lead 3b Semicircular groove part
4 Casting sand conveying means 5 Driving means 8 Sand testing means 9 Sand unraveling member 11 Collision member 12 Mold molding machine 101c Sand supply port 101d Sand discharge port 104 Foundry sand conveying means 107 Sand input chute 108 Sand testing means 112 Open / close type gate 112a Gate Plate 113 Sand temperature measuring means 114 Mold making machine 121 Sand cutting means 300 The first semicircular groove 301 The semicircular groove 302 after the second stage 302 The semicircular cross-sectional area 303 of the first semicircular groove From the second stage Semicircular cross section S of the semicircular groove part

Claims (14)

A sampling foundry sand supply device for sampling and feeding the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold making, and supplying the sand to the sand testing means,
A sand cutting device having a sand supply port at one end and a sand discharge port at the other end;
A sand throwing chute with one end communicating with the sand outlet of the sand cutting device and the other end communicating with the sand testing means;
An openable gate attached to the sand throwing chute;
A sand temperature measuring means for measuring the temperature of the foundry sand attached to the sand throwing chute and accumulated on the gate plate in the openable gate;
Comprising
The sand cutting device
An outer cylinder provided with the sand supply port at one end and the sand discharge port at the other end;
An inner cylinder fixed to the inner surface of the outer cylinder;
A foundry sand supply apparatus for sampling, which has a rotatable and solid screw that penetrates the inside of the inner cylinder and has one end inserted into the foundry sand conveying means and the other end connected to a driving means. . A sampling foundry sand supply device for sampling and feeding the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold making, and supplying the sand to the sand testing means,
A sand cutting device having a sand supply port at one end and a sand discharge port at the other end;
A sand throwing chute with one end communicating with the sand outlet of the sand cutting device and the other end communicating with the sand testing means;
An openable gate attached to the sand throwing chute;
A sand temperature measuring means for measuring the temperature of the foundry sand attached to the sand throwing chute and accumulated on the gate plate in the openable gate;
Comprising
When the openable gate is closed, by storing the foundry sand on the gate plate in the openable gate, the temperature of the foundry sand accumulated on the gate plate is measured by the sand temperature measuring means,
A sampling foundry sand supply device for supplying the sand testing means with the foundry sand from the sand cutting device or the foundry sand stored on the gate plate when the openable gate is opened.   3. The sampling foundry sand supply device according to claim 2, wherein the foundry sand conveying means is a belt conveyor which is disposed above the mold making machine and supplies the foundry sand to the mold making machine. A sand cutting device that samples and removes the foundry sand from the foundry sand conveying means for conveying the foundry sand used for mold making, and supplies the sand to the sand testing means,
An outer cylinder having a sand supply port at one end and a sand discharge port at the other end;
An inner cylinder fixed to the inner surface of the outer cylinder;
A sand cutting device comprising a rotatable and solid screw that penetrates the inside of the inner cylinder and has one end inserted into the foundry sand conveying means and the other end connected to a driving means.   The sand cutting device according to claim 4, wherein a semicircular groove is continuously formed between the leads of the screw.   The sand cutting device according to claim 5, wherein a semicircular cross-sectional area of the first semicircular groove in the screw is smaller than a semicircular cross-sectional area of the semicircular groove after the second stage.   The sand cutting device according to claim 6, wherein a tip portion of the screw has a tapered shape.   The sand cutting device according to any one of claims 4 to 7, wherein a material of the inner cylinder and the screw is ultra high molecular weight polyethylene.   9. A sand cutting device according to claim 8, wherein a sand loosening member for loosening foundry sand is fixed to the other end of the screw.   The sand cutting device according to claim 9, wherein a collision member that collides with the foundry sand to be discharged is disposed at the sand discharge port of the outer cylindrical body.   11. The sand cutting apparatus according to claim 10, wherein the foundry sand conveying means is a belt conveyor which is disposed above the mold making machine and supplies the foundry sand to the mold making machine. A sand cutting device having a sand supply port at one end and a sand discharge port at the other end;
A sand throwing chute with one end communicating with the sand outlet of the sand cutting device and the other end communicating with the sand testing means;
An openable gate attached to the sand throwing chute;
A sand temperature measuring means for measuring the temperature of the foundry sand attached to the sand throwing chute and accumulated on the gate plate in the openable gate;
Sampling foundry sand supply method for sampling sand sand from the foundry sand transporting means for transporting the foundry sand used for mold making and feeding it to the sand test means Because
A first supply of sampling sand taken out from the foundry sand conveying means and supplied to the sand testing means via the sand throwing chute by normally operating the sand cutting device with the openable gate open. Process,
Closing the openable gate during the first supply step, and storing casting sand on a gate plate in the openable gate;
Measuring the temperature of the foundry sand accumulated on the gate plate with the sand temperature measuring means;
A second supply step of opening the openable gate and supplying the sand found on the gate plate to the sand testing means;
Returning the foundry sand remaining in the sand cutting device to the foundry sand conveying means by reversely operating the sand cutting device;
A method for supplying foundry sand for sampling, comprising:   13. The method for supplying the foundry sand for sampling according to claim 12, wherein the foundry sand conveying means is a belt conveyor which is disposed above the mold making machine and supplies the foundry sand to the mold making machine. The sand cutting device
An outer cylinder provided with the sand supply port at one end and the sand discharge port at the other end;
An inner cylinder fixed to the inner surface of the outer cylinder;
2. A rotatable and solid screw that penetrates the inside of the inner cylinder and has one end inserted into the foundry sand conveying means and the other end connected to a driving means. 13. A method for supplying the foundry sand for sampling according to 13.