JP2017001064A - Processing equipment and processing method of casting sand - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide processing equipment and a processing method of casting sand capable of improving cooling of the casting and uniformization of moisture, by leveling a quantity of casting sand inputted to a sand cooler.SOLUTION: Processing equipment comprises a sand hopper for temporarily storing supplied casting sand, a sand carrying conveyor for carrying the casting sand stored in the sand hopper, water sprinkling means for sprinkling water on the casting sand in carrying by the sand carrying conveyor and a sand cooler for cooling while agitating the water-sprinkled casting sand supplied from the sand carrying conveyor, and the sand hopper is attached with upper part sand detection means for detecting the existence of the casting sand of an upper part in the sand hopper, lower part sand detection means for detecting the existence of casting sand of a lower part in the sand hopper and medium part sand detection means for detecting the existence of casting sand of a medium part being a position between the upper part and the lower part in the sand hopper, and a carrying speed of the casting sand in the sand carrying conveyor is varied based on a signal from the medium part sand detection means.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a casting sand processing facility and a processing method for processing casting sand collected by pouring into a molded mold and then separating the mold so that it can be used again for mold molding.

  Conventionally, in a processing facility for foundry sand, water is appropriately added to the foundry sand and the foundry sand is cooled by a stirring type sand cooling device. The addition of moisture to the foundry sand is performed by measuring the temperature of the foundry sand on the conveyor before being put into the sand cooling device, and adding an amount of moisture corresponding to the measured value. (For example, see Patent Document 1). Conventionally, a belt conveyor at a constant speed is adopted as the conveyor before being put into the sand cooling device.

JP-A-57-171541

  However, the amount of the foundry sand that is collected and supplied to the belt conveyor varies depending on the sand metal ratio of the poured mold, the production plan, and the like. If it does so, depending on the quantity of the foundry sand supplied to this belt conveyor, the stop time of a belt conveyor will become long, or the frequency of starting-stop of a belt conveyor will increase. For this reason, there is a problem that the amount of foundry sand put into the sand cooling device is not leveled, and cooling of the foundry sand and uniformity of moisture are reduced.

  The present invention has been made in view of the above problems, and improves the cooling of the foundry sand and the homogenization of moisture by leveling the amount of the foundry sand put into the sand cooling device. An object of the present invention is to provide a processing facility and a processing method for foundry sand.

  In order to achieve the above object, the foundry sand treatment facility of the present invention is a foundry sand treatment facility for treating the foundry sand so that it can be used for mold making, and temporarily stores the supplied foundry sand. A sand hopper, a sand transport conveyor for transporting the foundry sand stored in the sand hopper, a water spray means for spraying the foundry sand being transported by the sand transport conveyor, and a water spray supplied from the sand transport conveyor A sand cooling device that cools the cast sand while stirring, and the sand hopper includes upper sand detection means for detecting the presence or absence of the upper casting sand in the sand hopper, Lower part sand detection means for detecting the presence or absence of the foundry sand in the lower part in the sand hopper, and the presence or absence of the foundry sand in the middle part which is a position between the upper part and the lower part in the sand hopper The middle sand detection means Are characterized by varying the transport speed of the molding sand in the sand conveyor based on a signal from the middle part sand detecting means.

  In addition, the sand handling conveyor according to the present invention is configured such that the sand transport conveyor is driven by a drive motor whose rotation speed can be varied by an inverter, based on a signal from the middle sand detection means, By changing the number of rotations of the drive motor by the inverter, the transfer speed of the foundry sand in the sand transfer conveyor can be changed.

  Furthermore, the processing facility for foundry sand according to the present invention varies the amount of water sprayed on the foundry sand being transported by the sand transport conveyor in accordance with the variation of the transport speed of the foundry sand in the sand transport conveyor. And

  In order to achieve the above object, a method for treating foundry sand according to the present invention is a method for treating foundry sand using the foundry sand treatment facility according to claim 1, wherein the foundry sand is supplied to the sand hopper. And when the lower sand detecting means detects the presence of the foundry sand, driving the sand conveying conveyor at a first speed, and when the middle sand detecting means detects the presence of the foundry sand, Driving the sand transport conveyor at a second speed higher than the first speed; driving the sand transport conveyor at the first speed when the middle sand detecting means detects the absence of the foundry sand; And a step of stopping the driving of the sand conveying conveyor when the lower sand detecting means detects the absence of the foundry sand.

  The present invention is a processing equipment for foundry sand for treating the foundry sand so that it can be used for mold making, and a sand hopper for temporarily storing the supplied foundry sand, and the foundry stored in the sand hopper. Sand transporting conveyor for transporting sand, sprinkling means for sprinkling the foundry sand being transported by the sand transporting conveyor, and a sand cooling device for cooling the sprinkled foundry sand supplied from the sand transporting conveyor while stirring. The sand hopper includes upper part sand detection means for detecting the presence or absence of the upper part of the foundry sand in the sand hopper, and the presence or absence of the lower part of the foundry sand in the sand hopper. And a lower sand detecting means for detecting the presence or absence of the foundry sand in the middle part which is a position between the upper part and the lower part in the sand hopper. The signal from the middle sand detection means Based on the above, the speed of the foundry sand transported on the sand transport conveyor is made variable so that the amount of the foundry sand charged into the sand cooling device is leveled, and the foundry sand is cooled and the moisture is made uniform. There are various effects such as improvement.

It is a general | schematic block diagram which shows embodiment of this invention. It is an AA arrow line view in FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In FIG. 1, reference numeral 1 denotes a sand hopper disposed in a processing facility for foundry sand for treating the foundry sand (green sand in this embodiment) so as to be used for mold making. More specifically, in the present invention, the casting sand processing facility is a facility for processing the casting sand recovered by pouring the mold into molds and then separating the molds so that they can be used again for mold molding. Say that. Here, the mold separation means that the poured mold is collapsed and divided into products and foundry sand.

  The sand hopper 1 temporarily stores foundry sand supplied by sand supply means (not shown) (for example, a belt conveyor or a bucket elevator). The sand hopper 1 is equipped with upper part sand detecting means 2 for detecting the presence or absence of the upper part of the foundry sand in the sand hopper 1, and the presence or absence of the lower part of the foundry sand in the sand hopper 1 is detected. The lower sand detecting means 3 for detecting is mounted. Furthermore, a middle part sand detecting means 4 for detecting the presence or absence of the foundry sand at the middle part, which is a position between the upper part and the lower part in the sand hopper 1, is mounted. The upper sand detection means 2, the lower sand detection means 3 and the middle sand detection means 4 use level switches in the present embodiment, and the positions of all three can be adjusted.

  And the sand conveyance conveyor 5 which conveys the casting sand stored in the sand hopper 1 is arrange | positioned under the sand storage part 1a in the sand hopper 1, and the sand conveyance conveyor 5 is a belt conveyor in this embodiment. Used. The sand transport conveyor 5 has a configuration in which a belt 5c is wound around a front end pulley 5a and a rear end pulley 5b, and the belt 5c is rotated by rotating the front end pulley 5a by a drive motor 5d. The drive motor 5d and the tip pulley 5a are configured such that power is transmitted by a chain wheel and a chain (not shown).

  A chute 6 is connected to the lower part of the tip pulley 5 a in the sand transport conveyor 5, and the tip of the chute 6 is connected to one end side surface of a sand cooling device 7 disposed below the sand transport conveyor 5. . And the duct 8 is further connected with the one end side surface of the sand cooling device 7, and the front-end | tip of the duct 8 is connected with the dust collector 9. FIG.

  Reference numeral 10 denotes a moisture sensor for measuring the moisture of the foundry sand being conveyed by the sand conveyor 5. Reference numeral 11 denotes a temperature sensor for measuring the temperature of the foundry sand being conveyed by the sand conveying conveyor 5. Reference numeral 12 denotes a sand detection sensor that detects the presence or absence of foundry sand on the belt 5 c in the sand transport conveyor 5. The moisture sensor 10, the temperature sensor 11, and the sand detection sensor 12 are each disposed above the belt 5c.

  And the water spray means 13 which sprinkles water on the foundry sand currently conveyed with the sand conveyance conveyor 5 is arrange | positioned downstream of the moisture sensor 10 above the belt 5c. The water sprinkling means 13 is connected in communication with a water pipe 14, and the base end portion 14a of the water pipe 14 is connected to a water source (not shown). An on-off valve 21, an electromagnetic flow meter 15 and a proportional electromagnetic valve 16 are incorporated in the water pipe 14.

  Agitating means 17 for agitating the foundry sand being conveyed by the sand conveying conveyor 5 is disposed downstream of the water sprinkling means 13 above the belt 5c. The drive motor 5d is electrically connected to the inverter 18, and the inverter 18 can vary the rotation speed. Further, the lower part sand detection means 3 and the middle part sand detection means 4 are also electrically connected to the inverter 18.

  The inverter 18 is electrically connected to a sequencer (programmable logic controller) 20 incorporated in the control panel 19. The electromagnetic flow meter 15 and the proportional solenoid valve 16 are also electrically connected to the sequencer 20.

  Details of the sand cooling device 7 will be described. The sand cooling device 7 includes a rotating drum 7a. The rotating drum 7a is rotated in the direction of the arrow shown in FIG. 2 by rotating the main shaft 7c with a motor 7b. A plurality of stirring members 7d for stirring the foundry sand are fixed to the inner peripheral surface of the rotating drum 7a. The stirring member 7d lifts the casting sand upward and drops it so that it is more exposed to air and promotes cooling.

  A ventilator 7e is provided on the other side surface of the sand cooling device 7. When the dust cooler 9 sucks the inside of the sand cooling device 7, the air is introduced from the ventilator 7e. And the sand discharge port 7f is provided in the bottom part of the other end side of the sand cooling device 7, The foundry sand cooled while stirring in the rotating drum 7a is discharged | emitted from this sand discharge port 7f. The discharged foundry sand is sent to the next process via a hopper or chute (not shown).

  The operation of the apparatus configured as described above will be described. First, the sand cooling device 7, the dust collector 9, and the stirring means 17 are operated. The foundry sand is supplied into the empty sand hopper 1 from above the sand hopper 1 by the above-described sand supply means. In addition, since this sand supply means is act | operated intermittently, sand supply here is performed intermittently.

  When the foundry sand is supplied into the sand hopper 1, the foundry sand is gradually stored in the sand hopper 1. Then, first, the lower part sand detection means 3 detects “existence” of the foundry sand (detects a level switch “ON” signal). When the lower sand detection means 3 detects the presence of the foundry sand, the timer counts for a predetermined time (in this embodiment, 30 seconds), and then the drive motor 5d is operated to drive the sand transport conveyor 5 at the first speed. Let

  In addition, the 1st speed here means a comparatively low speed, and is a speed slower than the 2nd speed mentioned later. In addition, a signal indicating the presence of the foundry sand detected by the lower part sand detection means 3 is transmitted to the inverter 18, and based on this signal, the sand transport conveyor 5 is set to the first speed. The inverter 18 sets the rotation speed (rotation speed per unit time) of the drive motor 5d. Setting and changing the rotational speed of the drive motor 5d can be realized by setting and changing the frequency of the inverter 18. In the present embodiment, the first speed is 16.5 m / min, and the rotational speed of the drive motor 5d at the first speed is 14.8 rpm.

  And if the drive at the 1st speed of the sand conveyance conveyor 5 is started, the foundry sand in the sand hopper 1 will be cut out, and conveyance of the foundry sand in the sand conveyance conveyor 5 will be started. Next, after the sand detection sensor 12 detects the presence of foundry sand on the belt 5c, the moisture sensor 10 and the temperature sensor 11 measure the moisture and temperature of the foundry sand being conveyed.

  The target moisture and target temperature of the foundry sand discharged from the sand cooling device 7 are determined in advance. Therefore, in order to obtain the target moisture and target temperature, it is necessary to grasp how much water should be sprinkled on the foundry sand being conveyed. The necessary water spray amount is calculated by the sequencer 20 based on the measured moisture and temperature of the foundry sand being conveyed. Then, the opening degree of the proportional solenoid valve 16 is adjusted (changed) based on a command from the sequencer 20. Here, the amount of water sprinkled from the sprinkling means 13 is adjusted to the opening degree of the proportional solenoid valve 16 so that the calculated required sprinkling amount is obtained.

  The on-off valve 21 opens when the two conditions of driving the sand transport conveyor 5 and detecting the presence of the foundry sand of the sand detection sensor 12 are satisfied. For this reason, the calculated required watering amount of water is sprinkled from the watering means 13 to the foundry sand being conveyed. The amount of water flowing through the water pipe 14 is measured by an electromagnetic flow meter 15. Further, when the calculated required water spray amount is zero, that is, when it is not necessary to spray water, the proportional solenoid valve 16 is closed.

  Then, the sprinkled foundry sand is stirred by the stirring means 17 while being transported by the sand transport conveyor 5, then falls from the tip of the sand transport conveyor 5, and is supplied into the sand cooling device 7 through the chute 6. . The foundry sand supplied into the sand cooling device 7 advances toward the tip of the rotating drum 7a while being stirred in the rotating drum 7a as the rotating drum 7a rotates. Meanwhile, the atmosphere is introduced from the ventilator 7e by suction by the dust collector. As a result, the water is evaporated and the foundry sand is cooled by the heat of vaporization. The foundry sand reaching the sand discharge port 7f is discharged from the sand discharge port 7f and sent to the next step through the hopper or chute described above.

  When the foundry sand is further stored in the sand hopper 1, the middle sand detecting means 4 detects the presence of the foundry sand (detects a level switch “ON” signal). When the middle sand detecting means 4 detects the presence of the foundry sand, the timer counts for a predetermined time (in this embodiment, 10 seconds), and then the number of rotations of the drive motor 5d is varied to change the sand transport conveyor 5 to the first position. Drive at 2 speeds.

  The second speed here means a relatively high speed, which is a speed higher than the first speed described above. The casting sand “present” signal detected by the middle sand detecting means 4 is transmitted to the inverter 18, and based on this signal, the inverter is arranged so that the sand transport conveyor 5 is at the second speed. 18, the rotational speed of the drive motor 5d is varied. In the present embodiment, the second speed described above is 33 m / min, and the rotational speed of the drive motor 5d at the second speed is 29.6 rpm.

  Then, the amount of water sprayed on the foundry sand being transported by the sand transport conveyor 5 is varied in accordance with the change in the transport speed of the foundry sand in the sand transport conveyor 5. This point will be described in detail. The sequencer 20 calculates the required water spray amount when the sand transport conveyor 5 is at the second speed based on the signal transmitted from the inverter 18. Then, based on a command from the sequencer 20, the opening degree of the proportional solenoid valve 16 is adjusted.

  Here, the amount of water sprinkled from the sprinkling means 13 is adjusted to the opening degree of the proportional solenoid valve 16 such that the calculated amount of water sprayed when the sand transport conveyor 5 is at the second speed. In addition, since the quantity of the foundry sand conveyed is so large that the conveyance speed of the sand conveyance conveyor 5 is fast, the amount of required watering increases. Moreover, since the quantity of the foundry sand conveyed is so small that the conveyance speed of the sand conveyance conveyor 5 is slow, the amount of required watering decreases.

  Further, when the sand transport conveyor 5 continues to carry the foundry sand, the foundry sand in the sand hopper 1 gradually decreases. Then, the middle sand detecting means 4 detects “absence” of the foundry sand (detects a level switch “OFF” signal). Then, when the middle sand detecting means 4 detects “absence” of the foundry sand, after counting for a predetermined time (10 seconds in the present embodiment) by a timer, the rotational speed of the drive motor 5d is varied to make the sand transport conveyor 5 as described above. The first speed is driven.

  The casting sand “absent” signal detected by the middle sand detecting means 4 is transmitted to the inverter 18, and based on this signal, the sand conveying conveyor 5 is set to the first speed described above. Then, the rotation speed of the drive motor 5d is varied by the inverter 18.

  Then, the amount of water sprayed on the foundry sand being transported by the sand transport conveyor 5 is varied in accordance with the change in the transport speed of the foundry sand in the sand transport conveyor 5. The sequencer 20 calculates the necessary water spray amount when the sand transport conveyor 5 is at the first speed based on the signal transmitted from the inverter 18. Then, based on a command from the sequencer 20, the opening degree of the proportional solenoid valve 16 is adjusted. Here, the amount of water sprinkled from the sprinkling means 13 is adjusted to the opening degree of the proportional solenoid valve 16 so that the calculated amount of water sprayed when the sand transport conveyor 5 is the first speed described above. The

  When the foundry sand in the sand hopper 1 is changing in the vicinity of the middle sand detecting means 4, the middle sand detecting means 4 appropriately detects "present" or "no" of the foundry sand. Become. In this case, the above-described operation when the middle sand detecting means 4 detects “existence” of the foundry sand and the operation when the middle sand detecting means 4 detects “not present” of the foundry sand are repeated. It is.

  In addition, when the sand transport conveyor 5 continues to transport the foundry sand, the foundry sand in the sand hopper 1 further decreases. Then, the lower part sand detecting means 3 detects “absence” of the foundry sand (detects a level switch “OFF” signal). When the lower sand detecting means 3 detects “absence” of the foundry sand, the driving motor 5d is stopped after a predetermined time (3 seconds in the present embodiment) is counted by a timer, and the driving of the sand conveying conveyor 5 is stopped. The casting sand “absent” signal detected by the lower sand detecting means 3 is transmitted to the inverter 18, and the drive motor 5d is stopped based on this signal. And with the stop of the drive motor 5d, the on-off valve 21 is closed.

  The upper part sand detection means 2 detects the upper limit of the foundry sand stored in the sand hopper 1 so that the foundry sand does not overflow from the sand hopper 1. Therefore, when the upper sand detecting means 2 detects “existence” of the foundry sand (detects a level switch “ON” signal), the sand supplying means described above is forcibly stopped.

  In the present invention, the sand hopper 1 includes an upper part sand detecting means 2 for detecting the presence or absence of upper casting sand in the sand hopper 1 and a lower part for detecting the presence or absence of lower casting sand in the sand hopper 1. The partial sand detecting means 3 and the middle sand detecting means 4 for detecting the presence or absence of the foundry sand at the middle portion which is the position between the upper portion and the lower portion in the sand hopper 1 are mounted. Based on the signal from the position sand detection means 4, the transport speed of the foundry sand in the sand transport conveyor 5 is varied.

  According to this configuration, even if the amount of the foundry sand collected and supplied into the sand hopper 1 fluctuates, the foundry sand transport speed in the sand transport conveyor 5 based on the signal from the middle sand detecting means 4. Since the operating time of the sand transport conveyor 5 becomes longer due to the change, the stop time of the sand transport conveyor 5 can be shortened. In addition, the frequency of starting and stopping the sand transport conveyor 5 can be reduced. For this reason, the quantity of the foundry sand thrown into the sand cooling device 7 is leveled, and the cooling of the foundry sand and the uniformization of moisture can be improved. Moreover, since the frequency of starting and stopping of the sand transport conveyor 5 is reduced, there is an advantage that the load applied to the drive motor 5d is reduced.

  In the present invention, the sand transport conveyor 5 is driven by the drive motor 5d whose rotation speed can be varied by the inverter 18, and based on the signal from the middle sand detecting means 4, the inverter 18 By changing the number of rotations of the drive motor 5d, the transport speed of the foundry sand in the sand transport conveyor 5 is made variable. According to this structure, there exists an advantage that the conveyance speed of the foundry sand in the sand conveyance conveyor 5 can be changed easily.

  Further, according to the present invention, the amount of water sprayed on the foundry sand being transported by the sand transport conveyor 5 is varied with the variation of the transport speed of the foundry sand in the sand transport conveyor 5. According to this configuration, the optimal amount of water can be sprinkled with respect to the amount of foundry sand to be transported, which varies depending on the transport speed of the sand transport conveyor 5, and the uniformization of moisture in the foundry sand can be further improved. There is an advantage that you can.

  Further, in the present invention, the step of supplying the foundry sand to the sand hopper 1, the step of driving the sand transport conveyor 5 at the first speed when the lower sand detecting means 3 detects the presence of the foundry sand, and the middle sand detection. When the means 4 detects the presence of foundry sand, the step of driving the sand transport conveyor 5 at a second speed higher than the first speed, and when the middle sand detecting means 4 detects the absence of foundry sand, the sand transport conveyor 5 is A step of driving at one speed, and a step of stopping the driving of the sand conveying conveyor 5 when the lower sand detecting means 3 detects the absence of foundry sand.

  According to this configuration, even if the amount of the foundry sand collected and supplied into the sand hopper 1 fluctuates, the foundry sand transport speed in the sand transport conveyor 5 based on the signal from the middle sand detecting means 4. Since the operating time of the sand transport conveyor 5 becomes longer due to the change, the stop time of the sand transport conveyor 5 can be shortened. In addition, the frequency of starting and stopping the sand transport conveyor 5 can be reduced. For this reason, the quantity of the foundry sand thrown into the sand cooling device 7 is leveled, and the cooling of the foundry sand and the uniformization of moisture can be improved. Moreover, since the frequency of starting and stopping of the sand transport conveyor 5 is reduced, there is an advantage that the load applied to the drive motor 5d is reduced.

  In the embodiment of the present invention, when the lower sand detecting means 3 detects “present” or “absent” of the foundry sand, the driving motor 5d is activated or stopped after counting for a predetermined time by a timer. However, the step of counting for a predetermined time by the timer may be omitted. In addition, when the middle sand detecting means 4 detects “existence” or “absence” of the foundry sand, the number of rotations of the drive motor 5d is varied after a predetermined time is counted by a timer, but the present invention is limited to this. However, the step of counting for a predetermined time by the timer may be omitted.

  In the embodiment of the present invention, a belt conveyor is used as the sand transport conveyor 5. However, the present invention is not limited to this, and other conveyors may be used as long as the sand can be transported. Good.

DESCRIPTION OF SYMBOLS 1 Sand hopper 2 Upper part sand detection means 3 Lower part sand detection means 4 Middle part sand detection means 5 Sand conveyance conveyor 5d Drive motor 7 Sand cooling device 13 Sprinkling means 18 Inverter

Claims (4)

A processing facility for foundry sand for processing the foundry sand so that it can be used for mold making,
A sand hopper for temporarily storing the foundry sand to be supplied, a sand transport conveyor for transporting the foundry sand stored in the sand hopper, and a sprinkling means for sprinkling the foundry sand being transported by the sand transport conveyor And a sand cooling device that cools the sprinkled casting sand supplied from the sand conveyor while stirring.
The sand hopper includes upper part sand detection means for detecting the presence or absence of the upper part of the foundry sand in the sand hopper, and lower part sand detection means for detecting the presence or absence of the lower part of the foundry sand in the sand hopper And a middle part sand detecting means for detecting the presence or absence of the foundry sand in the middle part which is a position between the upper part and the lower part in the sand hopper,
A foundry sand treatment facility, wherein the sand sand transporting speed of the sand transport conveyor is varied based on a signal from the middle sand detecting means.   The sand transport conveyor is driven by a drive motor whose rotation speed can be varied by an inverter, and the rotation speed of the drive motor can be varied by the inverter based on a signal from the middle sand detection means. 2. The foundry sand treatment facility according to claim 1, wherein a speed of conveying the foundry sand on the sand conveying conveyor is varied.   The amount of water sprayed on the foundry sand being transported by the sand transport conveyor is varied in accordance with variation in the transport speed of the foundry sand in the sand transport conveyor. The foundry sand treatment facility.   A method for treating foundry sand using the foundry sand treatment facility according to claim 1, wherein the step of supplying the foundry sand to the sand hopper and the lower sand detecting means detects the presence of the foundry sand. Driving the sand transport conveyor at a first speed; driving the sand transport conveyor at a second speed higher than the first speed when the middle sand detecting means detects the presence of the foundry sand; When the middle sand detecting means detects the absence of the foundry sand, the step of driving the sand conveying conveyor at the first speed; and when the lower sand detecting means detects the absence of the foundry sand, the sand conveying conveyor. And a step of stopping the driving of the casting sand.