JPWO2018168164A1 - Binder supply device and method for supplying binder for foundry sand - Google Patents

Abstract

A binder supply device for supplying a liquid binder to molding sand according to the present invention includes a storage tank for storing a binder, a first pump for supplying the binder to the storage tank, and adjusting the temperature of the binder in the storage tank to a predetermined temperature. A second temperature control device, a second pump that circulates the binder by discharging the binder from the storage tank to the flow path, and again supplies the binder to the storage tank, and a flow meter that measures the flow rate of the binder flowing through the flow path. And a binder discharge port for discharging the binder.

Description

  The present invention relates to a binder supply device and a binder supply method for supplying a liquid binder to molding sand.

  DESCRIPTION OF RELATED ART Conventionally, the binder supply apparatus which supplies a liquid binder to molding sand is known by patent document 1, for example.

JP-A-8-976

  Conventionally, in a liquid binder supply device, the flow rate of a liquid binder flowing in a flow path is measured by a flow meter. However, in a space where the room temperature changes, the error in the measured flow rate increases each time the liquid temperature (the temperature of the liquid binder) changes, so that there has been a problem that the flow rate measurement cannot be performed with high accuracy.

  Therefore, the present invention has been made in order to solve the above-described problems, and is intended for a molding sand capable of performing high-accuracy flow measurement by maintaining a constant liquid temperature and reducing an error in a measured flow. It is an object to provide a binder supply device and a binder supply method.

  To achieve the above object, the present invention provides a binder supply device for supplying a liquid binder to foundry sand, a storage tank for storing the binder, a first pump for supplying the binder to the storage tank, and a storage tank. A temperature adjusting means for adjusting the temperature of the binder in the tank to a predetermined temperature; a second pump for circulating the binder by discharging the binder from the storage tank to the flow path and supplying the binder to the storage tank again; A flow meter for measuring the flow rate of the binder flowing through the binder, and a binder outlet for discharging the binder for kneading with the foundry sand.

  In the present invention, preferably, the flow meter is disposed downstream of the second pump, and further disposed downstream of the flow meter, and a direction in which a binder supplied from the second pump flows is supplied to the storage tank. And a three-way valve for switching to a side for supplying to the binder outlet.

  The present invention preferably further includes a bypass flow path for removing air mixed in the binder, the bypass flow path being connected to the downstream side of the second pump and the storage tank, and having a flow rate It is arranged to bypass the meter.

  The present invention preferably further includes an on-off valve disposed on the upstream side adjacent to the binder outlet.

  In the present invention, preferably, the molding sand is a core sand for core molding.

  In the present invention, the core sand is preferably a core sand for inorganic core molding.

  The present invention is a binder supply method for supplying a liquid binder to molding sand, comprising: supplying a binder to a storage tank by a first pump; and discharging the binder from the storage tank to a flow path by a second pump. Circulating the binder by supplying it again to the storage tank, adjusting the temperature of the binder in the storage tank to a predetermined temperature by the temperature adjusting means, and measuring the flow rate of the binder flowing through the flow path by the flow meter And

  Preferably, the present invention further comprises a three-way valve disposed downstream of the second pump via the flow meter, the direction in which the binder supplied from the second pump flows, the side supplying the storage tank and the binder discharge port. And a step of switching to the side for supplying to.

  In the present invention, preferably, when the binder supplied from the second pump is discharged from the binder discharge port, the binder is discharged from the binder discharge port by measuring the flow rate of the binder supplied from the second pump with a flow meter. The amount of the binder is grasped, and when the amount of the discharged binder reaches the set amount that is smaller than the target discharge amount, the second pump is changed to operate one pulse at a time.

  In the present invention, preferably, the binder supplied from the second pump is supplied to the storage tank and circulated, except when the binder supplied from the second pump is being discharged from the binder discharge port.

  In the present invention, preferably, the flow rate of the binder supplied from the second pump per pulse is reduced by operating the second pump one pulse at a time and adjusting the pulse period.

  According to the binder supply device and the binder supply method for supplying a liquid binder to the molding sand of the present invention, the temperature of the binder can be kept constant even in a room where the room temperature changes, and therefore, the error of the measured flow rate also decreases. Various effects can be achieved, for example, the size can be reduced and the flow rate can be measured with high accuracy.

1 is an overall configuration diagram illustrating a binder supply device according to an embodiment of the present invention.

  Hereinafter, a binder supply device and a binder supply method according to an embodiment of the present invention will be described with reference to the drawings. In the present embodiment, an example is shown in which a core sand for inorganic core molding (artificial sand in the present embodiment) is used as a molding sand, and a liquid binder (water glass in the present embodiment) is supplied thereto. In FIG. 1, reference numeral 1 denotes a binder storage container (a drum in this embodiment).

  The storage container 1 is connected to a first pump 3 (a pneumatic diaphragm pump in this embodiment) through a pipe 2. The first pump 3 is connected through a pipe 4 to the inlet side of the storage tank 5. By operating the first pump 3, the binder in the storage container 1 is supplied to the storage tank 5. On-off valves 6 and 7 are disposed upstream and downstream of the first pump 3 and in the middle of the pipes 2 and 4. A thermometer 25 is mounted on a side surface of the storage tank 5, and the temperature of the binder is measured by the thermometer 25 (a thermocouple in the present embodiment). Further, a level switch 26 is mounted in the storage tank 5 so that “empty” and “full” in the storage tank 5 can be detected.

  The binder supply device according to the present embodiment includes a temperature adjusting device 8 that adjusts the temperature of the binder in the storage tank 5 to a predetermined temperature. The temperature adjusting device 8 includes a circulating fluid temperature adjusting device 8a. The circulating fluid discharged from the circulating fluid temperature adjusting device 8a receives two stainless steels stored in the storage tank 5 from the inlet pipe 8b. It is supplied to the flexible tube 8c. After the circulating fluid passes through the flexible tube 8c, it is returned to the circulating fluid temperature controller 8a from the outlet pipe 8d. By repeating such a circulation of the binder, heat is exchanged in the flexible tube 8c, and the temperature of the binder is adjusted.

  The outlet side of the storage tank 5 is connected to a second pump 10 (in this embodiment, an electromagnetic diaphragm pump) through a pipe 9. The second pump 10 is connected to a flow meter 12 (a Coriolis flow meter in this embodiment) through a pipe 11. By operating the second pump 10, the binder is discharged from the storage tank 5. On-off valves 13 and 14 are disposed upstream and downstream of the second pump 10 and in the middle of the pipes 9 and 11.

  The flow meter 12 is connected to the inlet side of the three-way valve 16 via a pipe 15. An outlet on one side of the three-way valve 16 is connected to an inlet side of the storage tank 5 through a pipe 17. The outlet on the other side of the three-way valve 16 is connected through a pipe 18 to a binder outlet 19. The three-way valve 16 is pneumatically operated. When the pilot air is supplied to the three-way valve 16 from an electromagnetic valve (not shown), the direction in which the binder supplied from the second pump 10 flows is changed to the supply side (the pipe 17 side) to the storage tank 5 and the binder discharge port 19. It can be switched to the supply side (pipe 18 side).

  A check valve 20 and an on-off valve 21 are provided in the middle of the pipe 18. The on-off valve 21 is provided at a position on the upstream side adjacent to the binder discharge port 19. The on-off valve 21 is normally closed, and is opened by supplying pilot air from a solenoid valve (not shown).

  A pipe 22 branched from the pipe 11 and disposed in parallel with the flow meter 12 so as to bypass the flow meter 12 is connected to the inlet side of the storage tank 5. The pipe 22 forms a bypass flow path for removing air mixed in the binder. An on-off valve 23 is provided in the pipe 22 at a position parallel to the flow meter 12, and an on-off valve 24 is provided near the inlet side of the storage tank 5.

  Next, the operation of the above-described binder supply device according to the present embodiment and the binder supply method according to the present embodiment will be described. At the start, the on-off valves 6, 7, 13, and 14 are open, the on-off valves 23 and 24 are closed, and the on-off valve 21 is closed. In the three-way valve 16, the direction in which the binder flows is switched to the side that supplies the storage tank 5.

  When the level switch 26 detects that the inside of the storage tank 5 is “empty”, the first pump 3 is operated to supply the binder in the storage container 1 to the storage tank 5. When detecting that the state is “full”, the operation of the first pump 3 is stopped.

  Next, the second pump 10 is operated. Thereby, the binder is discharged from the storage tank 5, and the binder is supplied to the storage tank 5 again via the pipe 17. In this way, the binder is circulated and the circulation is repeated.

  While circulating the binder, the circulating fluid temperature controller 8a is operated to perform heat exchange in the flexible tube 8c. Thereby, the temperature of the binder in the storage tank 5 is adjusted to a predetermined temperature. At this time, since the binder is circulating, the temperatures of the storage tank 5 and the binder in each pipe can be kept constant.

  Next, the three-way valve 16 is switched, and the direction in which the binder flows is set to the side to be supplied to the binder outlet 19. Then, the on-off valve 21 is opened. Thereby, the binder is sent to the binder outlet 19 via the pipe 18 and is discharged from the binder outlet 19. The discharged binder is supplied to a kneader (not shown).

  When the binder supplied from the second pump 10 is discharged from the binder discharge port 19, the flow rate of the binder supplied from the second pump 10 is measured by the flow meter 12. Thereby, the amount of the binder discharged from the binder discharge port 19 is grasped. Then, when the amount of the discharged binder reaches a set amount that is smaller than the target discharge amount, the second pump 10 is changed to operate one pulse at a time. Thus, the amount of the binder discharged from the binder discharge port 19 can be finely adjusted, and the binder can be discharged with high accuracy. The operation of the second pump 10 one pulse at a time means that the supply of the binder from the second pump 10 and the stop of the supply are repeated at a predetermined pulse cycle (predetermined time) by repeating the discharge and suction of the second pump 10. is there.

  Thereafter, when the amount of the discharged binder reaches the target discharge amount, the on-off valve 21 is closed. Then, the three-way valve 16 is switched, and the direction in which the binder flows is set to the side to be supplied to the storage tank 5. As a result, the binder supplied from the second pump 10 is circulated again until the binder is discharged from the binder discharge port 19, and the temperature of the binder in the storage tank 5 and each pipe is kept constant. It is.

  Here, the binder supplied to a kneader (not shown) is kneaded together with a molding sand, a powdery binder and the like in the kneader to form wet sand. Using this wet sand, an inorganic core is formed by an inorganic core forming machine (not shown).

  Further, as described above, the binder supply device according to the present embodiment includes the pipe 22 which is a bypass flow path for removing air mixed in the binder. According to the binder supply device according to the present embodiment, there is an advantage that the binder can be circulated at high speed using the pipe 22, and the air mixed into the binder can be removed at high speed. When performing this air release, the on-off valves 23 and 24 are opened. Then, the binder is supplied to the inlet side of the storage tank 5 through the pipe 22 without reducing the flow rate by the flow meter 12. During the supply of the binder, the air mixed into the binder in the storage tank 5 is removed.

  Furthermore, in this embodiment, the flow rate of the binder supplied from the second pump 10 per pulse is reduced by operating the second pump 10 one pulse at a time and adjusting the pulse cycle to be shorter. You may. By doing so, the amount of the binder narrowed by the thin pipe in the flow meter 12 is reduced, and there is an advantage that the efficiency of the second pump 10 can be improved. Note that the pulse period is the elapsed time from this pulse to the next pulse.

  More specifically, when the pulse cycle of the second pump 10 is long, the flow rate of one pulse cycle from the second pump 10 increases. For this reason, the amount of the binder squeezed by the thin pipe in the flow meter 12 increases, and the efficiency of the second pump 10 deteriorates. Therefore, specifically, the pulse cycle of the second pump 10 is adjusted to be shorter. By doing so, the flow rate of each pulse from the second pump 10 decreases, and the amount of the binder narrowed by the thin pipe in the flow meter 12 also decreases. As a result, the efficiency of the second pump 10 can be improved.

  In the present embodiment, a flow meter 12 is provided downstream of the second pump 10, and a three-way valve 16 is provided downstream of the flow meter 12. The three-way valve 16 supplies the three-way valve 16 from the second pump 10. The direction in which the binder flows is switched between the side for supplying to the storage tank 5 and the side for supplying to the binder outlet 19. With such a configuration, the binder supplied from the second pump 10 can be supplied to the storage tank 5 and circulated except when the binder supplied from the second pump 10 is being discharged from the binder discharge port 19. There is an advantage that you can.

  Also, since the binder is constantly circulating except when discharged from the binder discharge port 19, the temperature of the binder in the storage tank 5 and the binder in each pipe is kept constant without separately installing a stirrer or the like. There is an advantage that can be.

  Further, in the present embodiment, since the on-off valve 21 is provided at a position on the upstream side adjacent to the binder discharge port 19, there is an advantage that the liquid dripping from the binder discharge port 19 can be suppressed.

  In the binder supply device of the present embodiment, each pipe is not particularly limited in material and structure as long as it forms a flow path of the binder. For example, it may be a tube member or a hose.

  Further, in the embodiment of the present invention, both the on-off valves 23 and 24 are opened when removing the air mixed in the binder, but the present invention is not limited to this. One of the on-off valves 23 and 24 may be opened.

  Further, in the above-described embodiment of the present invention, an example in which the binder is supplied to the core sand for inorganic core molding has been described, but the present invention is not limited to this. For example, if a process needs to supply a binder to the core sand, the present invention may be applied to a core molding process other than the inorganic core molding. Further, any process that requires a binder to be supplied to the green sand may be applied to a molding process using green sand. Further, any process that requires a binder to be supplied to the self-hardening molding sand may be applied to the self-hardening mold forming process.

3 First pump 5 Storage tank 8 Temperature controller 10 Second pump 12 Flow meter 16 Three-way valve 19 Binder outlet 21 Open / close valve 22 Piping (bypass flow path)

Claims (11)

A binder supply device for supplying a liquid binder to the molding sand,
A storage tank for storing the binder,
A first pump for supplying a binder to the storage tank,
Temperature adjusting means for adjusting the temperature of the binder in the storage tank to a predetermined temperature,
A second pump that circulates the binder by discharging the binder from the storage tank to the flow path and supplying the binder to the storage tank again,
A flow meter for measuring the flow rate of the binder flowing through the flow path,
A binder outlet for discharging a binder for kneading with the casting sand,
A binder supply device for foundry sand, comprising:   The flow meter is disposed downstream of a second pump, and further disposed downstream of the flow meter, and a direction in which a binder supplied from the second pump flows to the storage tank and a side that supplies the storage tank with the binder. The binder supply device for foundry sand according to claim 1, further comprising a three-way valve that switches to a side to supply to the discharge port.   Furthermore, a bypass flow path for removing air mixed in the binder is provided. The bypass flow path is connected to a downstream side of the second pump and the storage tank, and bypasses the flow meter. 3. The binder supply device for foundry sand according to claim 1, wherein the binder supply device is arranged to perform the following.   3. The binder supply device for foundry sand according to claim 1, further comprising an on-off valve disposed on an upstream side adjacent to the binder discharge port. 4.   The binder supply device for molding sand according to claim 1 or 2, wherein the molding sand is a core sand for core molding.   The binder supply device for molding sand according to claim 5, wherein the core sand is a core sand for inorganic core molding. A binder supply method for supplying a liquid binder to molding sand,
Supplying the binder to the storage tank by the first pump;
Discharging the binder from the storage tank to the flow path by the second pump and supplying the binder to the storage tank again, thereby circulating the binder;
Adjusting the temperature of the binder in the storage tank to a predetermined temperature by temperature adjusting means,
Measuring the flow rate of the binder flowing through the flow path with a flow meter,
A method for supplying a binder for molding sand.   Further, the direction in which the binder supplied from the second pump flows by a three-way valve arranged via the flow meter downstream of the second pump is supplied to the supply side to the storage tank and the binder discharge port. 8. The method for supplying a binder for foundry sand according to claim 7, further comprising the step of:   When discharging the binder supplied from the second pump from the binder discharge port, the amount of the binder discharged from the binder discharge port by measuring the flow rate of the binder supplied from the second pump with the flow meter 9. When the amount of the discharged binder reaches a set amount that is smaller than the target discharge amount, the second pump is changed to operate one pulse at a time. A method for supplying a binder for foundry sand as described above.   The binder supplied from the second pump is supplied to the storage tank and circulated, except when the binder supplied from the second pump is being discharged from the binder discharge port. 3. The method for supplying a binder for molding sand according to 1.).   The casting sand according to claim 7 or 8, wherein the second pump is operated one pulse at a time to adjust the pulse period, thereby reducing the flow rate of the binder supplied from the second pump per pulse. Binder supply method.

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